CSS Grid Layout Module Level 2

W3C Candidate Recommendation Draft,

This version:
https://www.w3.org/TR/2020/CRD-css-grid-2-20201218/
Latest published version:
https://www.w3.org/TR/css-grid-2/
Editor's Draft:
https://drafts.csswg.org/css-grid-2/
Previous Versions:
Implementation Report:
https://wpt.fyi/results/css/css-grid/subgrid
Issue Tracking:
CSSWG Issues Repository
CSSWG GitHub
Inline In Spec
Editors:
Tab Atkins Jr. (Google)
Elika J. Etemad / fantasai (Invited Expert)
(Microsoft)
Suggest an Edit for this Spec:
GitHub Editor

Abstract

This CSS module defines a two-dimensional grid-based layout system, optimized for user interface design. In the grid layout model, the children of a grid container can be positioned into arbitrary slots in a predefined flexible or fixed-size layout grid. Level 2 expands Grid by adding “subgrid” capabilities for nested grids to participate in the sizing of their parent grids.

CSS is a language for describing the rendering of structured documents (such as HTML and XML) on screen, on paper, etc.

Status of this document

This section describes the status of this document at the time of its publication. Other documents may supersede this document. A list of current W3C publications and the latest revision of this technical report can be found in the W3C technical reports index at https://www.w3.org/TR/.

This document was published by the CSS Working Group as a Candidate Recommendation Draft. Publication as a Candidate Recommendation does not imply endorsement by the W3C Membership. A Candidate Recommendation Draft integrates changes from the previous Candidate Recommendation that the Working Group intends to include in a subsequent Candidate Recommendation Snapshot.

This is a draft document and may be updated, replaced or obsoleted by other documents at any time. It is inappropriate to cite this document as other than work in progress.

Please send feedback by filing issues in GitHub (preferred), including the spec code “css-grid” in the title, like this: “[css-grid] …summary of comment…”. All issues and comments are archived. Alternately, feedback can be sent to the (archived) public mailing list [email protected].

This document is governed by the 15 September 2020 W3C Process Document.

This document was produced by a group operating under the W3C Patent Policy. W3C maintains a public list of any patent disclosures made in connection with the deliverables of the group; that page also includes instructions for disclosing a patent. An individual who has actual knowledge of a patent which the individual believes contains Essential Claim(s) must disclose the information in accordance with section 6 of the W3C Patent Policy.

The CSSWG has resolved to move CSS Grid Level 2 to Candidate Recommendation. This transition is merely pending editorial work to merge the CSS Grid Level 1 prose into this document.

1. Introduction

This section is not normative.

Grid Layout is a layout model for CSS that has powerful abilities to control the sizing and positioning of boxes and their contents. Unlike Flexible Box Layout, which is single-axis–oriented, Grid Layout is optimized for 2-dimensional layouts: those in which alignment of content is desired in both dimensions.

An example of flex layout:
		     two rows of items,
		     the first being three items a third of the space each,
		     and the second being five items, a fifth of the space each.
		     There is therefore alignment along the “rows”, but not along the “columns”.
Representative Flex Layout Example
An example of grid layout:
		     two rows of items,
		     the first being four items—the last of which spans both rows,
		     and the second being two items—the first of which spans the first two columns— plus the spanned item from the first row.
Representative Grid Layout Example

In addition, due to its ability to explicitly position items in the grid, Grid Layout allows dramatic transformations in visual layout structure without requiring corresponding markup changes. By combining media queries with the CSS properties that control layout of the grid container and its children, authors can adapt their layout to changes in device form factors, orientation, and available space, while preserving a more ideal semantic structuring of their content across presentations.

Although many layouts can be expressed with either Grid or Flexbox, they each have their specialties. Grid enforces 2-dimensional alignment, uses a top-down approach to layout, allows explicit overlapping of items, and has more powerful spanning capabilities. Flexbox focuses on space distribution within an axis, uses a simpler bottom-up approach to layout, can use a content-size–based line-wrapping system to control its secondary axis, and relies on the underlying markup hierarchy to build more complex layouts. It is expected that both will be valuable and complementary tools for CSS authors.

Grid Level 2 adds the subgrid feature: a subgridded axis is one which matches up its grid lines to lines in the element’s parent’s grid, and which derives the sizes of its tracks through this integration with the parent grid.

1.1. Background and Motivation

Image: Application layout example requiring horizontal and vertical alignment.
Application layout example requiring horizontal and vertical alignment.

As websites evolved from simple documents into complex, interactive applications, techniques for document layout, e.g. floats, were not necessarily well suited for application layout. By using a combination of tables, JavaScript, or careful measurements on floated elements, authors discovered workarounds to achieve desired layouts. Layouts that adapted to the available space were often brittle and resulted in counter-intuitive behavior as space became constrained. As an alternative, authors of many web applications opted for a fixed layout that cannot take advantage of changes in the available rendering space on a screen.

The capabilities of grid layout address these problems. It provides a mechanism for authors to divide available space for layout into columns and rows using a set of predictable sizing behaviors. Authors can then precisely position and size the building block elements of their application into the grid areas defined by the intersections of these columns and rows. The following examples illustrate the adaptive capabilities of grid layout, and how it allows a cleaner separation of content and style.

1.1.1. Adapting Layouts to Available Space

Let us consider the layout of a game in two columns and three rows: the game title in the top left corner, the menu below it, and the score in the bottom left with the game board occupying the top and middle cells on the right followed by game controls filling the bottom left. The left column is sized to exactly fit its contents (the game title, menu items, and score), with the right column filling the remaining space.
Five grid items arranged according to content size and available space.
As more space becomes available in larger screens, the middle row / right column are allowed to expand to fill that space.
Growth in the grid due to an increase in available space.

Grid layout can be used to intelligently resize elements within a webpage. The adjacent figures represent a game with five major components in the layout: the game title, stats area, game board, score area, and control area. The author’s intent is to divide the space for the game such that:

The following grid layout example shows how an author might achieve all the sizing, placement, and alignment rules declaratively.

/**
 * Define the space for each grid item by declaring the grid
 * on the grid container.
 */
#grid {
  /**
   * Two columns:
   *  1. the first sized to content,
   *  2. the second receives the remaining space
   *     (but is never smaller than the minimum size of the board
   *     or the game controls, which occupy this column [Figure 4])
   *
   * Three rows:
   *  3. the first sized to content,
   *  4. the middle row receives the remaining space
   *     (but is never smaller than the minimum height
   *      of the board or stats areas)
   *  5. the last sized to content.
   */
  display: grid;
  grid-template-columns:
    /* 1 */ auto
    /* 2 */ 1fr;
  grid-template-rows:
    /* 3 */ auto
    /* 4 */ 1fr
    /* 5 */ auto;
}

/* Specify the position of each grid item using coordinates on
 * the 'grid-row' and 'grid-column' properties of each grid item.
 */
#title    { grid-column: 1; grid-row: 1; }
#score    { grid-column: 1; grid-row: 3; }
#stats    { grid-column: 1; grid-row: 2; align-self: start; }
#board    { grid-column: 2; grid-row: 1 / span 2; }
#controls { grid-column: 2; grid-row: 3; justify-self: center; }
<div id="grid">
  <div id="title">Game Title</div>
  <div id="score">Score</div>
  <div id="stats">Stats</div>
  <div id="board">Board</div>
  <div id="controls">Controls</div>
</div>

Note: There are multiple ways to specify the structure of the grid and to position and size grid items, each optimized for different scenarios.

1.1.2. Source-Order Independence

Image: An arrangement suitable for portrait orientation.
An arrangement suitable for “portrait” orientation.
Image: An arrangement suitable for landscape orientation.
An arrangement suitable for “landscape“ orientation.

Continuing the prior example, the author also wants the game to adapt to different devices. Also, the game should optimize the placement of the components when viewed either in portrait or landscape orientation (Figures 6 and 7). By combining grid layout with media queries, the author is able to use the same semantic markup, but rearrange the layout of elements independent of their source order, to achieve the desired layout in both orientations.

The following example uses grid layout’s ability to name the space which will be occupied by a grid item. This allows the author to avoid rewriting rules for grid items as the grid’s definition changes.

@media (orientation: portrait) {
  #grid {
    display: grid;

    /* The rows, columns and areas of the grid are defined visually
     * using the grid-template-areas property.  Each string is a row,
     * and each word an area.  The number of words in a string
     * determines the number of columns. Note the number of words
     * in each string must be identical. */
    grid-template-areas: "title stats"
                         "score stats"
                         "board board"
                         "ctrls ctrls";

    /* The way to size columns and rows can be assigned with the
     * grid-template-columns and grid-template-rows properties. */
    grid-template-columns: auto 1fr;
    grid-template-rows: auto auto 1fr auto;
  }
}

@media (orientation: landscape) {
  #grid {
    display: grid;

    /* Again the template property defines areas of the same name,
     * but this time positioned differently to better suit a
     * landscape orientation. */
    grid-template-areas: "title board"
                         "stats board"
                         "score ctrls";

    grid-template-columns: auto 1fr;
    grid-template-rows: auto 1fr auto;
  }
}

/* The grid-area property places a grid item into a named
 * area of the grid. */
#title    { grid-area: title }
#score    { grid-area: score }
#stats    { grid-area: stats }
#board    { grid-area: board }
#controls { grid-area: ctrls }
<div id="grid">
  <div id="title">Game Title</div>
  <div id="score">Score</div>
  <div id="stats">Stats</div>
  <div id="board">Board</div>
  <div id="controls">Controls</div>
</div>

Note: The reordering capabilities of grid layout intentionally affect only the visual rendering, leaving speech order and navigation based on the source order. This allows authors to manipulate the visual presentation while leaving the source order intact and optimized for non-CSS UAs and for linear models such as speech and sequential navigation.

Grid item placement and reordering must not be used as a substitute for correct source ordering, as that can ruin the accessibility of the document.

1.2. Value Definitions

This specification follows the CSS property definition conventions from [CSS2] using the value definition syntax from [CSS-VALUES-3]. Value types not defined in this specification are defined in CSS Values & Units [CSS-VALUES-3]. Combination with other CSS modules may expand the definitions of these value types.

In addition to the property-specific values listed in their definitions, all properties defined in this specification also accept the CSS-wide keywords as their property value. For readability they have not been repeated explicitly.

2. Overview

This section is not normative.

Grid Layout controls the layout of its content through the use of a grid: an intersecting set of horizontal and vertical lines which create a sizing and positioning coordinate system for the grid container’s contents. Grid Layout features

Grid containers can be nested or mixed with flex containers as necessary to create more complex layouts.

2.1. Declaring the Grid

The tracks (rows and columns) of the grid are declared and sized either explicitly through the explicit grid properties or are implicitly created when items are placed outside the explicit grid. The grid shorthand and its sub-properties define the parameters of the grid. § 7 Defining the Grid

Below are some examples of grid declarations:

2.2. Placing Items

The contents of the grid container are organized into individual grid items (analogous to flex items), which are then assigned to predefined areas in the grid. They can be explicitly placed using coordinates through the grid-placement properties or implicitly placed into empty areas using auto-placement. § 8 Placing Grid Items

Below are some examples of grid placement declarations using the grid-area shorthand:
grid-area: a;          /* Place into named grid area “a”     */
grid-area: auto;       /* Auto-place into next empty area    */
grid-area: 2 / 4;      /* Place into row 2, column 4         */
grid-area: 1 / 3 / -1; /* Place into column 3, span all rows */
grid-area: header-start / sidebar-start / footer-end / sidebar-end;
                       /* Place using named lines            */

These are equivalent to the following grid-row + grid-column declarations:

grid-row: a;                         grid-column: a;
grid-row: auto;                      grid-column: auto;
grid-row: 2;                         grid-column: 4;
grid-row: 1 / -1;                    grid-column: 3;
grid-row: header-start / footer-end; grid-column: sidebar-start / sidebar-end;

They can further be decomposed into the grid-row-start/grid-row-end/grid-column-start/grid-column-end longhands, e.g.

grid-area: a;
/* Equivalent to grid-row-start: a; grid-column-start: a; grid-row-end: a; grid-column-end: a; */

grid-area: 1 / 3 / -1;
/* Equivalent to grid-row-start: 1; grid-column-start: 3; grid-row-end: -1; grid-column-end: auto; */

2.3. Sizing the Grid

Once the grid items have been placed, the sizes of the grid tracks (rows and columns) are calculated, accounting for the sizes of their contents and/or available space as specified in the grid definition.

The resulting sized grid is aligned within the grid container according to the grid container’s align-content and justify-content properties. § 11 Alignment and Spacing

The following example justifies all columns by distributing any extra space among them, and centers the grid in the grid container when it is smaller than 100vh.
main {
  grid: auto-flow 1fr / repeat(auto-fill, 5em);
  min-height: 100vh;
  justify-content: space-between;
  align-content: safe center;
}

Finally each grid item is sized and aligned within its assigned grid area, as specified by its own sizing [CSS2] and alignment properties [CSS-ALIGN-3].

3. Grid Layout Concepts and Terminology

In grid layout, the content of a grid container is laid out by positioning and aligning it into a grid. The grid is an intersecting set of horizontal and vertical grid lines that divides the grid container’s space into grid areas, into which grid items (representing the grid container’s content) can be placed. There are two sets of grid lines: one set defining columns that run along the block axis, and an orthogonal set defining rows along the inline axis. [CSS3-WRITING-MODES]

Image: Grid Lines.
Grid lines: Three in the block axis and four in the inline axis.

3.1. Grid Lines

Grid lines are the horizontal and vertical dividing lines of the grid. A grid line exists on either side of a column or row. They can be referred to by numerical index, or by an author-specified name. A grid item references the grid lines to determine its position within the grid using the grid-placement properties.

The following two examples both create three column grid lines and four row grid lines.

This first example demonstrates how an author would position a grid item using grid line numbers:

#grid {
  display: grid;
  grid-template-columns: 150px 1fr;
  grid-template-rows: 50px 1fr 50px;
}

#item1 { grid-column: 2;
         grid-row-start: 1; grid-row-end: 4; }

This second example uses explicitly named grid lines:

/* equivalent layout to the prior example, but using named lines */
#grid {
  display: grid;
  grid-template-columns: 150px [item1-start] 1fr [item1-end];
  grid-template-rows: [item1-start] 50px 1fr 50px [item1-end];
}

#item1 {
  grid-column: item1-start / item1-end;
  grid-row: item1-start / item1-end;
}

3.2. Grid Tracks and Cells

Grid track is a generic term for a grid column or grid row—in other words, it is the space between two adjacent grid lines. Each grid track is assigned a sizing function, which controls how wide or tall the column or row may grow, and thus how far apart its bounding grid lines are. Adjacent grid tracks can be separated by gutters but are otherwise packed tightly.

A grid cell is the intersection of a grid row and a grid column. It is the smallest unit of the grid that can be referenced when positioning grid items.

In the following example there are two columns and three rows. The first column is fixed at 150px. The second column uses flexible sizing, which is a function of the unassigned space in the grid, and thus will vary as the width of the grid container changes. If the used width of the grid container is 200px, then the second column is 50px wide. If the used width of the grid container is 100px, then the second column is 0px and any content positioned in the column will overflow the grid container.
#grid {
  display: grid;
  grid-template-columns: 150px 1fr;  /* two columns */
  grid-template-rows: 50px 1fr 50px; /* three rows  */
}

3.3. Grid Areas

A grid area is the logical space used to lay out one or more grid items. A grid area consists of one or more adjacent grid cells. It is bound by four grid lines, one on each side of the grid area, and participates in the sizing of the grid tracks it intersects. A grid area can be named explicitly using the grid-template-areas property of the grid container, or referenced implicitly by its bounding grid lines. A grid item is assigned to a grid area using the grid-placement properties.

/* using the template syntax */
#grid  {
  display: grid;
  grid-template-areas: ". a"
                       "b a"
                       ". a";
  grid-template-columns: 150px 1fr;
  grid-template-rows: 50px 1fr 50px;
}

#item1 { grid-area: a }
#item2 { grid-area: b }
#item3 { grid-area: b }

/* Align items 2 and 3 at different points in the grid area "b".  */
/* By default, grid items are stretched to fit their grid area    */
/* and these items would layer one over the other. */
#item2 { align-self: start; }
#item3 { justify-self: end; align-self: end; }

A grid item’s grid area forms the containing block into which it is laid out. Grid items placed into the same grid area do not directly affect each other’s layout. Indirectly, however, a grid item occupying a grid track with an intrinsic sizing function can affect the size of that track (and thus the positions of its bounding grid lines), which in turn can affect the position or size of another grid item.

3.4. Nested vs. Subgridded Items

A grid item can itself be a grid container by giving it display: grid. In the general case the layout of this nested grid’s contents will be independent of the layout of the parent grid it participates in.

However, in some cases it might be necessary for the contents of multiple grid items to align to each other. A nested grid can defer the definition of its rows and/or columns to its parent grid container, making it a subgrid. In this case, the grid items of the subgrid participate in sizing the parent grid, allowing the contents of both grids to align. See § 9 Subgrids.

A subgrid is established by the subgrid keyword of grid-template-rows or grid-template-columns, and can be subgridded in either axis or in both. A grid that has no subgridded axis is a standalone grid.

For example, suppose we have a form consisting of a list of inputs with labels:
<ul>
  <li><label>Name:</label> <input name=fn>
  <li><label>Address:</label> <input name=address>
  <li><label>Phone:</label> <input name=phone>
</ul>

We want the labels and inputs to align, and we want to style each list item with a border. This can be accomplished with subgrid layout:

ul {
  display: grid;
  grid: auto-flow / auto 1fr;
}
li {
  grid-column: span 2;
  display: grid;
  grid-template-columns: subgrid;
  border: solid;
}
label {
  grid-column: 1;
}
input {
  grid-column: 2;
}

4. Reordering and Accessibility

Grid layout gives authors great powers of rearrangement over the document. However, these are not a substitute for correct ordering of the document source. The order property and grid placement do not affect ordering in non-visual media (such as speech). Likewise, rearranging grid items visually does not affect the default traversal order of sequential navigation modes (such as cycling through links, see e.g. tabindex [HTML]).

Authors must use order and the grid-placement properties only for visual, not logical, reordering of content. Style sheets that use these features to perform logical reordering are non-conforming.

Note: This is so that non-visual media and non-CSS UAs, which typically present content linearly, can rely on a logical source order, while grid layout’s placement and ordering features are used to tailor the visual arrangement. (Since visual perception is two-dimensional and non-linear, the desired visual order is not always equivalent to the desired reading order.)

Many web pages have a similar shape in the markup, with a header on top, a footer on bottom, and then a content area and one or two additional columns in the middle. Generally, it’s desirable that the content come first in the page’s source code, before the additional columns. However, this makes many common designs, such as simply having the additional columns on the left and the content area on the right, difficult to achieve. This has been addressed in many ways over the years, often going by the name "Holy Grail Layout" when there are two additional columns. Grid Layout makes this example trivial. For example, take the following sketch of a page’s code and desired layout:
<!DOCTYPE html>
<header>...</header>
<article>...</article>
<nav>...</nav>
<aside>...</aside>
<footer>...</footer>
In this page the header is at the top and the footer at the bottom, but the article is in the center, flanked by the nav on the right and the aside on the left.

This layout can be easily achieved with grid layout:

body { display: grid;
       grid: "h h h"
             "a b c"
             "f f f";
       grid-template-columns: auto 1fr 20%; }
article { grid-area: b; min-width: 12em;     }
nav     { grid-area: a; /* auto min-width */ }
aside   { grid-area: c; min-width: 12em;     }

As an added bonus, the columns will all be equal-height by default, and the main content will be as wide as necessary to fill the screen. Additionally, this can then be combined with media queries to switch to an all-vertical layout on narrow screens:

@media all and (max-width: 60em) {
  /* Too narrow to support three columns */
  main { display: block; }
}

In order to preserve the author’s intended ordering in all presentation modes, authoring tools—including WYSIWYG editors as well as Web-based authoring aids—must reorder the underlying document source and not use order or grid-placement properties to perform reordering unless the author has explicitly indicated that the underlying document order (which determines speech and navigation order) should be out-of-sync with the visual order.

For example, a tool might offer both drag-and-drop arrangement of grid items as well as handling of media queries for alternate layouts per screen size range.

Since most of the time, reordering should affect all screen ranges as well as navigation and speech order, the tool would match the resulting drag-and-drop visual arrangement by simultaneously reordering the DOM layer. In some cases, however, the author may want different visual arrangements per screen size. The tool could offer this functionality by using the grid-placement properties together with media queries, but also tie the smallest screen size’s arrangement to the underlying DOM order (since this is most likely to be a logical linear presentation order) while using grid-placement properties to rearrange the visual presentation in other size ranges.

This tool would be conformant, whereas a tool that only ever used the grid-placement properties to handle drag-and-drop grid rearrangement (however convenient it might be to implement it that way) would be non-conformant.

5. Grid Containers

5.1. Establishing Grid Containers: the grid and inline-grid display values

Name: display
New values: grid | inline-grid
grid
This value causes an element to generate a grid container box that is block-level when placed in flow layout.
inline-grid
This value causes an element to generate an grid container box that is inline-level when placed in flow layout.

A grid container that is not a subgrid establishes an independent grid formatting context for its contents. This is the same as establishing an independent block formatting context, except that grid layout is used instead of block layout: floats do not intrude into the grid container, and the grid container’s margins do not collapse with the margins of its contents. The contents of a grid container are laid out into a grid, with grid lines forming the boundaries of each grid items’ containing block.

Unlike those of a regular nested grid, a subgrid’s contents participate in its parent grid formatting context; thus a subgrid does not establish an independent formatting context.

Grid containers are not block containers, and so some properties that were designed with the assumption of block layout don’t apply in the context of grid layout. In particular:

If an element’s specified display is inline-grid and the element is floated or absolutely positioned, the computed value of display is grid. The table in CSS 2.1 Chapter 9.7 is thus amended to contain an additional row, with inline-grid in the "Specified Value" column and grid in the "Computed Value" column.

5.2. Sizing Grid Containers

Note see [CSS-SIZING-3] for a definition of the terms in this section.

A grid container is sized using the rules of the formatting context in which it participates:

In both inline and block formatting contexts, the grid container’s auto block size is its max-content size.

The block layout spec should probably define this, but it isn’t written yet.

The max-content size (min-content size) of a grid container is the sum of the grid container’s track sizes (including gutters) in the appropriate axis, when the grid is sized under a max-content constraint (min-content constraint).

5.3. Scrollable Grid Overflow

The overflow property applies to grid containers.

Just as it is included in intrinsic sizing (see above), the grid is also included in a grid container’s scrollable overflow region.

Note: Beware the interaction with padding when the grid container is a scroll container: additional padding is defined to be added to the scrollable overflow rectangle as needed to enable place-content: end alignment of scrollable content. See CSS Overflow 3 §2.2 Scrollable Overflow

5.4. Limiting Large Grids

Since memory is limited, UAs may clamp the possible size of the implicit grid to be within a UA-defined limit (which should accommodate lines at in the range [-10000, 10000]), dropping all lines outside that limit. If a grid item is placed outside this limit, its grid area must be clamped to within this limited grid.

To clamp a grid area:

For example, if a UA only supported grids with at most 1000 tracks in each dimension, the following placement properties:
.grid-item {
  grid-row: 500 / 1500;
  grid-column: 2000 / 3000;
}

Would end up being equivalent to:

.grid-item {
  grid-row: 500 / 1001;
  grid-column: 1000 / 1001;
}

6. Grid Items

Loosely speaking, the grid items of a grid container are boxes representing its in-flow contents.

Each in-flow child of a grid container becomes a grid item, and each contiguous sequence of child text runs is wrapped in an anonymous block container grid item. However, if the entire sequence of child text runs contains only white space (i.e. characters that can be affected by the white-space property) it is instead not rendered (just as if its text nodes were display:none).

Examples of grid items:

<div style="display: grid">

  <!-- grid item: block child -->
  <div id="item1">block</div>

  <!-- grid item: floated element; floating is ignored -->
  <div id="item2" style="float: left;">float</div>

  <!-- grid item: anonymous block box around inline content -->
  anonymous item 3

  <!-- grid item: inline child -->
  <span>
    item 4
    <!-- grid items do not split around blocks -->
    <q style="display: block" id=not-an-item>item 4</q>
    item 4
  </span>
</div>
grid items determined from above code block
  1. grid item containing block.
  2. grid item containing float.
  3. (Anonymous, unstyleable) grid item containing anonymous item 3.
  4. grid item containing three blocks in succession:
    • Anonymous block containing item 4.
    • <q> element block containing item 4.
    • Anonymous block containing item 4.

Note: inter-element white space disappears: it does not become its own grid item, even though inter-element text does get wrapped in an anonymous grid item.

Note: The box of a anonymous item is unstyleable, since there is no element to assign style rules to. Its contents will however inherit styles (such as font settings) from the grid container.

6.1. Grid Item Display

Unless it is a subgrid, a grid item establishes an independent formatting context for its contents. However, grid items are grid-level boxes, not block-level boxes: they participate in their container’s grid formatting context, not in a block formatting context.

If the computed display value of an element’s nearest ancestor element (skipping display:contents ancestors) is grid or inline-grid, the element’s own display value is blockified. (See CSS2.1§9.7 [CSS2] and CSS Display 3 §2.7 Automatic Box Type Transformations for details on this type of display value conversion.)

Note: Blockification still occurs even when the grid or inline-grid element does not end up generating a grid container box, e.g. when it is replaced or in a display: none subtree.

Note: Some values of display normally trigger the creation of anonymous boxes around the original box. If such a box is a grid item, it is blockified first, and so anonymous box creation will not happen. For example, two contiguous grid items with display: table-cell will become two separate display: block grid items, instead of being wrapped into a single anonymous table.

6.2. Grid Item Sizing

A grid item is sized within the containing block defined by its grid area.

Grid item calculations for automatic sizes in a given dimensions vary by their self-alignment values:

normal

If the grid item is a replaced element with a natural size in the relevant dimension (or with a preferred aspect ratio and a natural size in the other dimension) the grid item is sized as for align-self: start (consistent with the width calculation rules for block-level replaced elements in CSS 2 §10.3.4 Block-level, replaced elements in normal flow).

Otherwise, if the grid item has a preferred aspect ratio, the grid item is sized as for a block-level box.

Otherwise, the grid item is sized as for stretch.

stretch

Use the inline size calculation rules for non-replaced boxes (defined in CSS 2 §10.3.3 Block-level, non-replaced elements in normal flow).

Note: This can distort the aspect ratio of an item with a preferred aspect ratio, if its size is also constrained in the other axis.

all other values

Size the item as fit-content.

The following informative table summarizes the automatic sizing of grid items:
Summary of automatic sizing behavior of grid items
Alignment Non-replaced Element Size Replaced Element Size
normal Fill grid area Use natural size
stretch Fill grid area Fill grid area
start/center/etc. fit-content sizing (like floats) Use natural size

Note: The auto value of min-width and min-height affects track sizing in the relevant axis similar to how it affects the main size of a flex item. See § 6.6 Automatic Minimum Size of Grid Items.

6.3. Reordered Grid Items: the order property

The order property also applies to grid items. It affects their auto-placement and painting order.

As with reordering flex items, the order property must only be used when the visual order needs to be out-of-sync with the speech and navigation order; otherwise the underlying document source should be reordered instead. See CSS Flexbox 1 §5.4.1 Reordering and Accessibility in [CSS-FLEXBOX-1].

6.4. Grid Item Margins and Paddings

As adjacent grid items are independently contained within the containing block formed by their grid areas, the margins of adjacent grid items do not collapse.

Percentage margins and paddings on grid items, like those on block boxes, are resolved against the inline size of their containing block, e.g. left/right/top/bottom percentages all resolve against their containing block’s width in horizontal writing modes.

Auto margins expand to absorb extra space in the corresponding dimension, and can therefore be used for alignment. See § 11.2 Aligning with auto margins

6.5. Z-axis Ordering: the z-index property

Grid items can overlap when they are positioned into intersecting grid areas, or even when positioned in non-intersecting areas because of negative margins or positioning. The painting order of grid items is exactly the same as inline blocks [CSS2], except that order-modified document order is used in place of raw document order, and z-index values other than auto create a stacking context even if position is static (behaving exactly as if position were relative). Thus the z-index property can easily be used to control the z-axis order of grid items.

Note: Descendants that are positioned outside a grid item still participate in any stacking context established by the grid item.

The following diagram shows several overlapping grid items, with a combination of implicit source order and explicit z-index used to control their stacking order.
Drawing order controlled by z-index and source order.
<style type="text/css">
#grid {
  display: grid;
  grid-template-columns: 1fr 1fr;
  grid-template-rows: 1fr 1fr
}
#A { grid-column: 1 / span 2; grid-row: 2; align-self: end; }
#B { grid-column: 1; grid-row: 1; z-index: 10; }
#C { grid-column: 2; grid-row: 1; align-self: start; margin-left: -20px; }
#D { grid-column: 2; grid-row: 2; justify-self: end; align-self: start; }
#E { grid-column: 1 / span 2; grid-row: 1 / span 2;
     z-index: 5; justify-self: center; align-self: center; }
</style>

<div id="grid">
  <div id="A">A</div>
  <div id="B">B</div>
  <div id="C">C</div>
  <div id="D">D</div>
  <div id="E">E</div>
</div>

6.6. Automatic Minimum Size of Grid Items

Note: Much of the sizing terminology used in this section (and throughout the rest of the specification) is defined in CSS Intrinsic and Extrinsic Sizing [CSS-SIZING-3].

To provide a more reasonable default minimum size for grid items, the used value of its automatic minimum size in a given axis is the content-based minimum size if all of the following are true:

Otherwise, the automatic minimum size is zero, as usual.

The content-based minimum size for a grid item in a given dimension is its specified size suggestion if it exists, otherwise its transferred size suggestion if that exists, else its content size suggestion, see below. However, if in a given dimension the grid item spans only grid tracks that have a fixed max track sizing function, then its specified size suggestion and content size suggestion in that dimension (and its input from this dimension to the transferred size suggestion in the opposite dimension) are further clamped to less than or equal to the stretch fit into the grid area’s maximum size in that dimension, as represented by the sum of those grid tracksmax track sizing functions plus any intervening fixed gutters.

In all cases, the size suggestion is additionally clamped by the maximum size in the affected axis, if it’s definite.

Note: The argument to fit-content() does not clamp the content-based minimum size in the same way as a fixed max track sizing function.

The content size suggestion, specified size suggestion, and transferred size suggestion used in this calculation account for the relevant min/max/preferred size properties so that the content-based minimum size does not interfere with any author-provided constraints, and are defined below:

specified size suggestion
If the item’s preferred size in the relevant axis is definite, then the specified size suggestion is that size. It is otherwise undefined.
transferred size suggestion
If the item has a preferred aspect ratio and its preferred size in the opposite axis is definite, then the transferred size suggestion is that size (clamped by the opposite-axis minimum and maximum sizes if they are definite), converted through the aspect ratio. It is otherwise undefined.
content size suggestion
The content size suggestion is the min-content size in the relevant axis, clamped, if it has a preferred aspect ratio, by any definite opposite-axis minimum and maximum sizes converted through the aspect ratio.

For the purpose of calculating an intrinsic size of the box (e.g. the box’s min-content size), a content-based minimum size causes the box’s size in that axis to become indefinite (even if e.g. its width property specifies a definite size). Note this means that percentages calculated against this size will behave as auto.

Nonetheless, although this may require an additional layout pass to re-resolve percentages in some cases, this value (like the min-content, max-content, and fit-content values defined in [CSS-SIZING-3]) does not prevent the resolution of percentage sizes within the item.

Note that while a content-based minimum size is often appropriate, and helps prevent content from overlapping or spilling outside its container, in some cases it is not:

In particular, if grid layout is being used for a major content area of a document, it is better to set an explicit font-relative minimum width such as min-width: 12em. A content-based minimum width could result in a large table or large image stretching the size of the entire content area, potentially into an overflow zone, and thereby making lines of text needlessly long and hard to read.

Note also, when content-based sizing is used on an item with large amounts of content, the layout engine must traverse all of this content before finding its minimum size, whereas if the author sets an explicit minimum, this is not necessary. (For items with small amounts of content, however, this traversal is trivial and therefore not a performance concern.)

7. Defining the Grid

7.1. The Explicit Grid

The three properties grid-template-rows, grid-template-columns, and grid-template-areas together define the explicit grid of a grid container by specifying its explicit grid tracks. The final grid may end up larger due to grid items placed outside the explicit grid; in this case implicit tracks will be created, these implicit tracks will be sized by the grid-auto-rows and grid-auto-columns properties.

The size of the explicit grid is determined by the larger of the number of rows/columns defined by grid-template-areas and the number of rows/columns sized by grid-template-rows/grid-template-columns. Any rows/columns defined by grid-template-areas but not sized by grid-template-rows/grid-template-columns take their size from the grid-auto-rows/grid-auto-columns properties. If these properties don’t define any explicit tracks the explicit grid still contains one grid line in each axis.

Numeric indexes in the grid-placement properties count from the edges of the explicit grid. Positive indexes count from the start side (starting from 1 for the start-most explicit line), while negative indexes count from the end side (starting from -1 for the end-most explicit line).

The grid and grid-template properties are shorthands that can be used to set all three explicit grid properties (grid-template-rows, grid-template-columns, and grid-template-areas) at the same time. The grid shorthand also resets properties controlling the implicit grid, whereas the grid-template property leaves them unchanged.

7.2. Explicit Track Sizing: the grid-template-rows and grid-template-columns properties

Name: grid-template-columns, grid-template-rows
Value: none | <track-list> | <auto-track-list> | subgrid <line-name-list>?
Initial: none
Applies to: grid containers
Inherited: no
Percentages: refer to corresponding dimension of the content area
Computed value: the keyword none or a computed track list
Canonical order: per grammar
Animation type: if the list lengths match, by computed value type per item in the computed track list (see § 7.2.5 Computed Value of a Track Listing and § 7.2.3.3 Interpolation/Combination of repeat()); discrete otherwise

These properties specify, as a space-separated track list, the line names and track sizing functions of the grid. The grid-template-columns property specifies the track list for the grid’s columns, while grid-template-rows specifies the track list for the grid’s rows.

Values have the following meanings:

none
Indicates that no explicit grid tracks are created by this property (though explicit grid tracks could still be created by grid-template-areas).

Note: In the absence of an explicit grid any rows/columns will be implicitly generated, and their size will be determined by the grid-auto-rows and grid-auto-columns properties.

<track-list> | <auto-track-list>
Specifies the track list as a series of track sizing functions and line names. Each track sizing function can be specified as a length, a percentage of the grid container’s size, a measurement of the contents occupying the column or row, or a fraction of the free space in the grid. It can also be specified as a range using the minmax() notation, which can combine any of the previously mentioned mechanisms to specify separate min and max track sizing functions for the column or row.
subgrid <line-name-list>?
The subgrid value indicates that the grid will adopt the spanned portion of its parent grid in that axis (the subgridded axis). Rather than being specified explicitly, the sizes of the grid rows/columns will be taken from the parent grid's definition, and the subgrid’s items will participate in the intrinsic size calculations (CSS Grid Layout 1 §11.5 Resolve Intrinsic Track Sizes) of any tracks shared with the parent grid. Essentially, subgrids provide the ability to pass grid parameters down through nested elements, and content-based sizing information back up to their parent grid.

The <line-name-list> argument allows local naming of the grid lines shared with the parent grid: if a <line-name-list> is given, the specified <line-names>s are assigned to the lines of the subgrid’s explicit grid, one per line, starting with line 1. Excess <line-names> are ignored.

If there is no parent grid, this value is equivalent to the initial value, none, and the grid container is not a subgrid.

An axis that is not subgridded is a standalone axis.

The syntax of a track list is:

<track-list>          = [ <line-names>? [ <track-size> | <track-repeat> ] ]+ <line-names>?
<auto-track-list>     = [ <line-names>? [ <fixed-size> | <fixed-repeat> ] ]* <line-names>? <auto-repeat>
                        [ <line-names>? [ <fixed-size> | <fixed-repeat> ] ]* <line-names>?
<explicit-track-list> = [ <line-names>? <track-size> ]+ <line-names>?

<line-name-list>      = [ <line-names> | <name-repeat> ]+
<track-size>          = <track-breadth> | minmax( <inflexible-breadth> , <track-breadth> ) | fit-content( <length-percentage> )
<fixed-size>          = <fixed-breadth> | minmax( <fixed-breadth> , <track-breadth> ) | minmax( <inflexible-breadth> , <fixed-breadth> )
<track-breadth>       = <length-percentage> | <flex> | min-content | max-content | auto
<inflexible-breadth>  = <length-percentage> | min-content | max-content | auto
<fixed-breadth>       = <length-percentage>
<line-names>          = '[' <custom-ident>* ']'

Where the component values are defined as follows…

7.2.1. Track Sizes

<length-percentage>
A non-negative length or percentage, as defined by CSS3 Values. [CSS-VALUES-3]

<percentage> values are relative to the inner inline size of the grid container in column grid tracks, and the inner block size of the grid container in row grid tracks. If the size of the grid container depends on the size of its tracks, then the <percentage> must be treated as auto, for the purpose of calculating the intrinsic sizes of the grid container and then resolve against that resulting grid container size for the purpose of laying out the grid and its items.

<flex>
A non-negative dimension with the unit fr specifying the track’s flex factor. Each <flex>-sized track takes a share of the remaining space in proportion to its flex factor. For example, given a track listing of 1fr 2fr, the tracks will take up ⅓ and ⅔ of the leftover space, respectively. See § 7.2.4 Flexible Lengths: the fr unit for more details.

Note: If the sum of the flex factors is less than 1, they’ll take up only a corresponding fraction of the leftover space, rather than expanding to fill the entire thing.

When appearing outside a minmax() notation, implies an automatic minimum (i.e. ''minmax(auto, <flex>)'').

minmax(min, max)
Defines a size range greater than or equal to min and less than or equal to max. If the max is less than the min, then the max will be floored by the min (essentially yielding minmax(min, min)). As a maximum, a <flex> value sets the track’s flex factor; it is invalid as a minimum.

Note: A future level of this spec may allow <flex> minimums, and will update the track sizing algorithm to account for this correctly

auto
As a maximum: represents the largest max-content contribution of the grid items occupying the grid track; however, unlike max-content, allows expansion of the track by the align-content and justify-content properties.

As a minimum: represents the largest minimum size (specified by min-width/min-height) of the grid items occupying the grid track. (This initially is often, but not always, equal to a min-content minimum—see § 6.6 Automatic Minimum Size of Grid Items.)

When appearing outside a minmax() notation: equivalent to minmax(auto, auto), representing the range between the minimum and maximum described above. (This behaves similar to minmax(min-content, max-content) in the most basic cases, but with extra abilities.)

max-content
Represents the largest max-content contribution of the grid items occupying the grid track.
min-content
Represents the largest min-content contribution of the grid items occupying the grid track.
fit-content( <length-percentage> )
Represents the formula max(minimum, min(limit, max-content)), where minimum represents an auto minimum (which is often, but not always, equal to a min-content minimum), and limit is the track sizing function passed as an argument to fit-content(). This is essentially calculated as the smaller of minmax(auto, max-content) and minmax(auto, limit).
Given the following grid-template-columns declaration:
grid-template-columns: 100px 1fr max-content minmax(min-content, 1fr);

Five grid lines are created:

  1. At the start edge of the grid container.
  2. 100px from the start edge of the grid container.
  3. A distance from the previous line equal to half the free space (the width of the grid container, minus the width of the non-flexible grid tracks).
  4. A distance from the previous line equal to the maximum size of any grid items belonging to the column between these two lines.
  5. A distance from the previous line at least as large as the largest minimum size of any grid items belonging to the column between these two lines, but no larger than the other half of the free space.

If the non-flexible sizes (100px, max-content, and min-content) sum to larger than the grid container’s width, the final grid line will be a distance equal to their sum away from the start edge of the grid container (the 1fr sizes both resolve to 0). If the sum is less than the grid container’s width, the final grid line will be exactly at the end edge of the grid container. This is true in general whenever there’s at least one <flex> value among the grid track sizes.

Additional examples of valid grid track definitions:
/* examples of valid track definitions */
grid-template-rows: 1fr minmax(min-content, 1fr);
grid-template-rows: 10px repeat(2, 1fr auto minmax(30%, 1fr));
grid-template-rows: calc(4em - 5px);

Note: The size of the grid is not purely the sum of the track sizes, as row-gap, column-gap and justify-content, align-content can add additional space between tracks.

7.2.2. Naming Grid Lines: the [<custom-ident>*] syntax

While grid lines can always be referred to by their numerical index, line names can make the grid-placement properties easier to understand and maintain. Line names can be explicitly assigned with the grid-template-rows and grid-template-columns properties, or implicitly assigned by named grid areas with the grid-template-areas property.

For example, the following code gives meaningful names to all of the lines in the grid. Note that some of the lines have multiple names.
#grid {
  display: grid;
  grid-template-columns: [first nav-start] 150px [main-start] 1fr [last];
  grid-template-rows: [first header-start] 50px [main-start] 1fr [footer-start] 50px [last];
}
Image: Named Grid Lines.
Named Grid Lines.

A line name cannot be span or auto, i.e. the <custom-ident> in the <line-names> production excludes the keywords span and auto.

7.2.3. Repeating Rows and Columns: the repeat() notation

The repeat() notation represents a repeated fragment of the track list, allowing a large number of columns or rows that exhibit a recurring pattern to be written in a more compact form.

This example shows two equivalent ways of writing the same grid definition. Both declarations produce four “main” columns, each 250px wide, surrounded by 10px “gutter” columns.
grid-template-columns: 10px [col-start] 250px [col-end]
                       10px [col-start] 250px [col-end]
                       10px [col-start] 250px [col-end]
                       10px [col-start] 250px [col-end] 10px;
/* same as above, except easier to write */
grid-template-columns: repeat(4, 10px [col-start] 250px [col-end]) 10px;
7.2.3.1. Syntax of repeat()

The generic form of the repeat() syntax is, approximately,

repeat( [ <integer [1,∞]> | auto-fill | auto-fit ] , <track-list> )

The first argument specifies the number of repetitions. The second argument is a track list, which is repeated that number of times. However, there are some restrictions:

Thus the precise syntax of the repeat() notation has several forms:

<track-repeat> = repeat( [ <integer [1,∞]> ] , [ <line-names>? <track-size> ]+ <line-names>? )
<auto-repeat>  = repeat( [ auto-fill | auto-fit ] , [ <line-names>? <fixed-size> ]+ <line-names>? )
<fixed-repeat> = repeat( [ <integer [1,∞]> ] , [ <line-names>? <fixed-size> ]+ <line-names>? )
<name-repeat> = repeat( [ <integer [1,∞]> | auto-fill ], <line-names>+)

If a repeat() function that is not a <name-repeat> ends up placing two <line-names> adjacent to each other, the name lists are merged. For example, repeat(2, [a] 1fr [b]) is equivalent to [a] 1fr [b a] 1fr [b].

7.2.3.2. Repeat-to-fill: auto-fill and auto-fit repetitions

On a subgridded axis, the auto-fill keyword is only valid once per <line-name-list>, and repeats enough times for the name list to match the subgrid’s specified grid span (falling back to 0 if the span is already fulfilled).

Otherwise on a standalone axis, when auto-fill is given as the repetition number, if the grid container has a definite size or max size in the relevant axis, then the number of repetitions is the largest possible positive integer that does not cause the grid to overflow the content box of its grid container (treating each track as its max track sizing function if that is definite or as its minimum track sizing function otherwise, flooring the max track sizing function by the min track sizing function if both are definite, and taking gap into account); if any number of repetitions would overflow, then 1 repetition. Otherwise, if the grid container has a definite min size in the relevant axis, the number of repetitions is the smallest possible positive integer that fulfills that minimum requirement. Otherwise, the specified track list repeats only once.

For example, the following code will create as many 25-character columns as will fit into the window width. If there is any remaining space, it will be distributed among the 25-character columns.
body {
  display: grid;
  grid-template-columns: repeat(auto-fill, minmax(25ch, 1fr));
}

The auto-fit keyword behaves the same as auto-fill, except that after grid item placement any empty repeated tracks are collapsed. An empty track is one with no in-flow grid items placed into or spanning across it. (This can result in all tracks being collapsed, if they’re all empty.)

A collapsed track is treated as having a fixed track sizing function of 0px, and the gutters on either side of it—including any space allotted through distributed alignmentcollapse.

For the purpose of finding the number of auto-repeated tracks in a standalone axis, the UA must floor the track size to a UA-specified value to avoid division by zero. It is suggested that this floor be 1px.

7.2.3.3. Interpolation/Combination of repeat()

If two repeat() notations that have the same first argument (repetition count) and the same number of tracks in their second argument (the track listing), they are combined by combining each component of their computed track lists by computed value (just like combining a top-level track list). They otherwise combine discretely.

7.2.4. Flexible Lengths: the fr unit

A flexible length or <flex> is a dimension with the fr unit, which represents a fraction of the leftover space in the grid container. Tracks sized with fr units are called flexible tracks as they flex in response to leftover space similar to how flex items with a zero base size fill space in a flex container.

The distribution of leftover space occurs after all non-flexible track sizing functions have reached their maximum. The total size of such rows or columns is subtracted from the available space, yielding the leftover space, which is then divided among the flex-sized rows and columns in proportion to their flex factor.

Each column or row’s share of the leftover space can be computed as the column or row’s <flex> * <leftover space> / <sum of all flex factors>.

<flex> values between 0fr and 1fr have a somewhat special behavior: when the sum of the flex factors is less than 1, they will take up less than 100% of the leftover space.

A track’s <flex> value is effectively a request for some proportion of the leftover space, with 1fr meaning “100% of the leftover space”; then if the tracks in that axis are requesting more than 100% in total, the requests are rebalanced to keep the same ratio but use up exactly 100% of it. However, if the tracks request less than the full amount (such as three tracks that are each .25fr) then they’ll each get exactly what they request (25% of the leftover space to each, with the final 25% left unfilled). See § 12.7 Expand Flexible Tracks for the exact details of how leftover space is distributed.

This pattern is required for continuous behavior as fr values approach zero (which means the tracks wants none of the leftover space). Without this, a 1fr track would take all of the leftover space; but so would a 0.1fr track, and a 0.01fr track, etc., until finally the value is small enough to underflow to zero and the track suddenly takes up none of the leftover space. With this behavior, the track instead gradually takes less of the leftover space as its flex factor shrinks below 1fr, smoothly transitioning to taking none of the leftover space at zero.

Unless this “partial fill” behavior is specifically what’s desired, authors should stick to values ≥ 1; for example, using 1fr and 2fr is usually better than using .33fr and .67fr, as they’re more likely to behave as intended if tracks are added or removed.

When the available space is infinite (which happens when the grid container’s width or height is indefinite), flex-sized grid tracks are sized to their contents while retaining their respective proportions. The used size of each flex-sized grid track is computed by determining the max-content size of each flex-sized grid track and dividing that size by the respective flex factor to determine a “hypothetical 1fr size”. The maximum of those is used as the resolved 1fr length (the flex fraction), which is then multiplied by each grid track’s flex factor to determine its final size.

Note: <flex> values are not <length>s (nor are they compatible with <length>s, like some <percentage> values), so they cannot be represented in or combined with other unit types in calc() expressions.

7.2.5. Computed Value of a Track Listing

The computed track list of a standalone axis is a list alternating between line name sets and track sections, with the first and last items being line name sets.

A line name set is a (potentially empty) set of identifiers representing line names.

A track section is either:

The computed track list of a subgridded axis is the subgrid keyword followed by a list of line name sets representing each line in that axis.

7.2.6. Resolved Value of a Track Listing

The grid-template-rows and grid-template-columns properties are resolved value special case properties. [CSSOM]

7.2.6.1. Resolved Value of a Standalone Track Listing

When an element generates a grid container box, the resolved value of its grid-template-rows or grid-template-columns property in a standalone axis is the used value, serialized with:

The first bullet point of the above list means that implicit tracks get serialized as part of grid-template-rows/etc., despite the fact that an author cannot actually specify implicit track sizes in those properties! So grid-template-rows and grid-template-columns values might not round-trip correctly:
const s = getComputedStyle(gridEl);
gridEl.style.gridTemplateRows = s.gridTemplateRows;
// Code like this should be a no-op,
// but if there are any implicit rows,
// this will convert them into explicit rows,
// possibly changing how grid items are positioned
// and altering the overall size of the grid!

This is an accidental property of an early implementation that leaked into later implementations without much thought given to it. We intend to remove it from the spec, but not until after we’ve defined a CSSOM API for getting information about implicit tracks, as currently this is the only way to get that information and a number of pages rely on that.

Otherwise, (e.g. when the element has display: none or is not a grid container) the resolved value is simply the computed value.

<style>
#grid {
  width: 500px;
  grid-template-columns:
    [a]     auto
    [b]     minmax(min-content, 1fr)
    [b c d] repeat(2, [e] 40px)
            repeat(5, auto);
}
</style>
<div id="grid">
  <div style="grid-column-start: 1; width: 50px"></div>
  <div style="grid-column-start: 9; width: 50px"></div>
</div>
<script>
  var gridElement = document.getElementById("grid");
  getComputedStyle(gridElement).gridTemplateColumns;
  // [a] 50px [b] 320px [b c d e] 40px [e] 40px 0px 0px 0px 0px 50px
</script>

Note: In general, resolved values are the computed values, except for a small list of legacy 2.1 properties. However, compatibility with early implementations of this module requires us to define grid-template-rows and grid-template-columns as returning used values.

The CSS Working Group is considering whether to also return used values for the grid-placement properties and is looking for feedback, especially from implementors. See discussion.

7.2.6.2. Resolved Value of a Subgridded Track Listing

When an element generates a grid container box that is a subgrid, the resolved value of the grid-template-rows and grid-template-columns properties represents the used number of columns, serialized as the subgrid keyword followed by a list representing each of its lines as a line name set of all the line’s names explicitly defined on the subgrid (not including those adopted from the parent grid), without using the repeat() notation.

For example, when applied to a subgrid with grid-column: span 4, each of the following grid-template-columns specified values becomes the corresponding resolved values:
specified: subgrid [a] repeat(auto-fill, [b]) [c]
resolved:  subgrid [a] [b] [b] [b] [c]
specified: subgrid [a] [a] [a] [a] repeat(auto-fill, [b]) [c] [c]
resolved:  subgrid [a] [a] [a] [a] [c]
specified: subgrid [] [a]
resolved:  subgrid [] [a] [] [] []
specified: subgrid [a] [b] [c] [d] [e] [f]
resolved:  subgrid [a] [b] [c] [d] [e]

Note: This violates the general "shortest equivalent serialization" principle by serializing empty trailing line name sets, as the trailing line name sets provide potentially-useful information about how many tracks the subgrid is spanning.

7.3. Named Areas: the grid-template-areas property

Name: grid-template-areas
Value: none | <string>+
Initial: none
Applies to: grid containers
Inherited: no
Percentages: n/a
Computed value: the keyword none or a list of string values
Canonical order: per grammar
Animation type: discrete

This property specifies named grid areas, which are not associated with any particular grid item, but can be referenced from the grid-placement properties. The syntax of the grid-template-areas property also provides a visualization of the structure of the grid, making the overall layout of the grid container easier to understand.

Values have the following meanings:

none
Indicates that no named grid areas, and likewise no explicit grid tracks, are defined by this property (though explicit grid tracks could still be created by grid-template-columns or grid-template-rows).

Note: In the absence of an explicit grid any rows/columns will be implicitly generated, and their size will be determined by the grid-auto-rows and grid-auto-columns properties.

<string>+
A row is created for every separate string listed for the grid-template-areas property, and a column is created for each cell in the string, when parsed as follows:

Tokenize the string into a list of the following tokens, using longest-match semantics:

  • A sequence of name code points, representing a named cell token with a name consisting of its code points.
  • A sequence of one or more "." (U+002E FULL STOP), representing a null cell token.
  • A sequence of whitespace, representing nothing (do not produce a token).
  • A sequence of any other characters, representing a trash token.

Note: These rules can produce cell names that do not match the <ident> syntax, such as "1st 2nd 3rd", which requires escaping when referencing those areas by name in other properties, like grid-row: \31st; to reference the area named 1st.

All strings must define the same number of cell tokens (named cell tokens and/or null cell tokens), and at least one cell token, or else the declaration is invalid. If a named grid area spans multiple grid cells, but those cells do not form a single filled-in rectangle, the declaration is invalid.

Note: Non-rectangular or disconnected regions may be permitted in a future version of this module.

In this example, the grid-template-areas property is used to create a page layout where areas are defined for header content (head), navigational content (nav), footer content (foot), and main content (main). Accordingly, the template creates three rows and two columns, with four named grid areas. The head area spans both columns and the first row of the grid.
#grid {
  display: grid;
  grid-template-areas: "head head"
                       "nav  main"
                       "foot ...."
}
#grid > header { grid-area: head; }
#grid > nav    { grid-area: nav; }
#grid > main   { grid-area: main; }
#grid > footer { grid-area: foot; }

7.3.1. Serialization Of Template Strings

When serializing either the specified or computed value of a <string> value of grid-template-areas, each null cell token is serialized as a single "." (U+002E FULL STOP), and consecutive cell tokens are separated by a single space (U+0020 SPACE), with all other white space elided.

7.3.2. Implicitly-Assigned Line Names

The grid-template-areas property generates implicitly-assigned line names from the named grid areas in the template. For each named grid area foo, four implicitly-assigned line names are created: two named foo-start, naming the row-start and column-start lines of the named grid area, and two named foo-end, naming the row-end and column-end lines of the named grid area.

These implicitly-assigned line names behave just like any other line names, except that they do not appear in the value of grid-template-rows/grid-template-columns. Even if an explicitly-assigned line name with the same name is defined, the implicitly-assigned line names are just more lines with the same name.

7.3.3. Implicitly-Named Areas

Since a named grid area is referenced by the implicitly-assigned line names it produces, explicitly adding named lines of the same form (foo-start/foo-end) effectively creates a named grid area. Such implicitly-named areas do not appear in the value of grid-template-areas, but can still be referenced by the grid-placement properties.

7.4. Explicit Grid Shorthand: the grid-template property

Name: grid-template
Value: none | [ <'grid-template-rows'> / <'grid-template-columns'> ] | [ <line-names>? <string> <track-size>? <line-names>? ]+ [ / <explicit-track-list> ]?
Initial: none
Applies to: grid containers
Inherited: see individual properties
Percentages: see individual properties
Computed value: see individual properties
Animation type: see individual properties
Canonical order: per grammar

The grid-template property is a shorthand for setting grid-template-columns, grid-template-rows, and grid-template-areas in a single declaration. It has several distinct syntax forms:

none
Sets all three properties to their initial values (none).
<'grid-template-rows'> / <'grid-template-columns'>
Sets grid-template-rows and grid-template-columns to the specified values, respectively, and sets grid-template-areas to none.
grid-template: auto 1fr / auto 1fr auto;

is equivalent to

grid-template-rows: auto 1fr;
grid-template-columns: auto 1fr auto;
grid-template-areas: none;
[ <line-names>? <string> <track-size>? <line-names>? ]+ [ / <explicit-track-list> ]?

This syntax allows the author to align track names and sizes inline with their respective grid areas.

grid-template: [header-top] "a   a   a"     [header-bottom]
                 [main-top] "b   b   b" 1fr [main-bottom]
                          / auto 1fr auto;

is equivalent to

grid-template-areas: "a a a"
                     "b b b";
grid-template-rows: [header-top] auto [header-bottom main-top] 1fr [main-bottom];
grid-template-columns: auto 1fr auto;

and creates the following grid:

  • Three columns, sized auto, 1fr, and auto, respectively
  • Two rows sized as auto and 1fr, respectively.
  • A line named both “header-top” and “a-start” at the top, a line with four names—“header-bottom”, “main-top”, “a-end”, and “b-start”—in the middle, a line named “main-bottom” and “b-end” at the bottom.
  • A line named “a-start” and “b-start” on the left edge, and a line named “a-end” and “b-end” on the right edge.
The grid created by the declarations above. (The “a/b-start/end” names are implicitly assigned by the named grid areas.)

Note: Note that the repeat() function isn’t allowed in these track listings, as the tracks are intended to visually line up one-to-one with the rows/columns in the “ASCII art”.

Note: The grid shorthand accepts the same syntax, but also resets the implicit grid properties to their initial values. Unless authors want those to cascade in separately, it is therefore recommended to use grid instead of grid-template.

7.5. The Implicit Grid

The grid-template-rows, grid-template-columns, and grid-template-areas properties define a fixed number of tracks that form the explicit grid. When grid items are positioned outside of these bounds, the grid container generates implicit grid tracks by adding implicit grid lines to the grid. These lines together with the explicit grid form the implicit grid. The grid-auto-rows and grid-auto-columns properties size these implicit grid tracks, as well as any explicit grid tracks created by grid-template-areas but not explicitly sized by grid-template-rows or grid-template-columns

The grid-auto-flow property controls auto-placement of grid items without an explicit position. Once the explicit grid is filled (or if there is no explicit grid) auto-placement will also cause the generation of implicit grid tracks.

The grid shorthand property can set the implicit grid properties (grid-auto-flow, grid-auto-rows, and grid-auto-columns) together with the explicit grid properties in a single declaration.

7.6. Implicit Track Sizing: the grid-auto-rows and grid-auto-columns properties

Name: grid-auto-columns, grid-auto-rows
Value: <track-size>+
Initial: auto
Applies to: grid containers
Inherited: no
Percentages: see Track Sizing
Computed value: see Track Sizing
Canonical order: per grammar
Animation type: by computed value type

The grid-auto-columns and grid-auto-rows properties specify the size of tracks not assigned a size by grid-template-rows or grid-template-columns. If multiple track sizes are given, the pattern is repeated as necessary to find the size of the affected tracks. The first track after the last explicitly-sized track receives the first specified size, and so on forwards; and the last implicit grid track before the explicit grid receives the last specified size, and so on backwards.

Note: If a grid item is positioned into a row or column that is not explicitly declared by grid-template-rows/grid-template-columns and/or grid-template-areas, implicit grid tracks are created to hold it. This can happen either by explicitly positioning into a row or column that is out of range, or by the auto-placement algorithm creating additional rows or columns.

<style>
  #grid {
    display: grid;
    grid-template-columns: 20px;
    grid-auto-columns: 40px;
    grid-template-rows: 20px;
    grid-auto-rows: 40px;
  }
  #A { grid-column: 1; grid-row: 1; }
  #B { grid-column: 2; grid-row: 1; }
  #C { grid-column: 1; grid-row: 2; }
  #D { grid-column: 2; grid-row: 2; }
</style>

<div id="grid">
  <div id="A">A</div>
  <div id="B">B</div>
  <div id="C">C</div>
  <div id="D">D</div>
</div>
A 2×2 grid with one explicit 20px×20px grid cell in the first row+column and three additional cells resulting from the implicit 40px column and row generated to hold the additional grid items.

7.7. Automatic Placement: the grid-auto-flow property

Name: grid-auto-flow
Value: [ row | column ] || dense
Initial: row
Applies to: grid containers
Inherited: no
Percentages: n/a
Computed value: specified keyword(s)
Canonical order: per grammar
Animation type: discrete

Grid items that aren’t explicitly placed are automatically placed into an unoccupied space in the grid container by the auto-placement algorithm. grid-auto-flow controls how the auto-placement algorithm works, specifying exactly how auto-placed items get flowed into the grid. See § 8.5 Grid Item Placement Algorithm for details on precisely how the auto-placement algorithm works.

row
The auto-placement algorithm places items by filling each row in turn, adding new rows as necessary. If neither row nor column is provided, row is assumed.
column
The auto-placement algorithm places items by filling each column in turn, adding new columns as necessary.
dense
If specified, the auto-placement algorithm uses a “dense” packing algorithm, which attempts to fill in holes earlier in the grid if smaller items come up later. This may cause items to appear out-of-order, when doing so would fill in holes left by larger items.

If omitted, a “sparse” algorithm is used, where the placement algorithm only ever moves “forward” in the grid when placing items, never backtracking to fill holes. This ensures that all of the auto-placed items appear “in order”, even if this leaves holes that could have been filled by later items.

Note: A future level of this module is expected to add a value that flows auto-positioned items together into a single “default” cell.

Auto-placement takes grid items in order-modified document order.

In the following example, there are three columns, each auto-sized to their contents. No rows are explicitly defined. The grid-auto-flow property is row which instructs the grid to search across its three columns starting with the first row, then the next, adding rows as needed until sufficient space is located to accommodate the position of any auto-placed grid item.
Image: A form arranged using automatic placement.

A form arranged using automatic placement.

<style type="text/css">
form {
  display: grid;
  /* Define three columns, all content-sized,
     and name the corresponding lines. */
  grid-template-columns: [labels] auto [controls] auto [oversized] auto;
  grid-auto-flow: row dense;
}
form > label {
  /* Place all labels in the "labels" column and
     automatically find the next available row. */
  grid-column: labels;
  grid-row: auto;
}
form > input, form > select {
  /* Place all controls in the "controls" column and
     automatically find the next available row. */
  grid-column: controls;
  grid-row: auto;
}

#department-block {
  /* Auto place this item in the "oversized" column
     in the first row where an area that spans three rows
     won’t overlap other explicitly placed items or areas
     or any items automatically placed prior to this area. */
  grid-column: oversized;
  grid-row: span 3;
}

/* Place all the buttons of the form
   in the explicitly defined grid area. */
#buttons {
  grid-row: auto;

  /* Ensure the button area spans the entire grid element
     in the inline axis. */
  grid-column: 1 / -1;
  text-align: end;
}
</style>
<form>
  <label for="firstname">First name:</label>
  <input type="text" id="firstname" name="firstname" />
  <label for="lastname">Last name:</label>
  <input type="text" id="lastname" name="lastname" />
  <label for="address">Address:</label>
  <input type="text" id="address" name="address" />
  <label for="address2">Address 2:</label>
  <input type="text" id="address2" name="address2" />
  <label for="city">City:</label>
  <input type="text" id="city" name="city" />
  <label for="state">State:</label>
  <select type="text" id="state" name="state">
    <option value="WA">Washington</option>
  </select>
  <label for="zip">Zip:</label>
  <input type="text" id="zip" name="zip" />

  <div id="department-block">
    <label for="department">Department:</label>
    <select id="department" name="department" multiple>
      <option value="finance">Finance</option>
      <option value="humanresources">Human Resources</option>
      <option value="marketing">Marketing</option>
    </select>
  </div>

  <div id="buttons">
    <button id="cancel">Cancel</button>
    <button id="back">Back</button>
    <button id="next">Next</button>
  </div>
</form>

7.8. Grid Definition Shorthand: the grid property

Name: grid
Value: <'grid-template'> | <'grid-template-rows'> / [ auto-flow && dense? ] <'grid-auto-columns'>? | [ auto-flow && dense? ] <'grid-auto-rows'>? / <'grid-template-columns'>
Initial: none
Applies to: grid containers
Inherited: see individual properties
Percentages: see individual properties
Computed value: see individual properties
Animation type: see individual properties
Canonical order: per grammar

The grid property is a shorthand that sets all of the explicit grid properties (grid-template-rows, grid-template-columns, and grid-template-areas), and all the implicit grid properties (grid-auto-rows, grid-auto-columns, and grid-auto-flow), in a single declaration. (It does not reset the gutter properties.) Its syntax matches grid-template, plus an additional syntax form for defining auto-flow grids:

<'grid-template-rows'> / [ auto-flow && dense? ] <'grid-auto-columns'>?
[ auto-flow && dense? ] <'grid-auto-rows'>? / <'grid-template-columns'>
Sets up auto-flow, by setting the tracks in one axis explicitly (setting either grid-template-rows or grid-template-columns as specified, and setting the other to none), and specifying how to auto-repeat the tracks in the other axis (setting either grid-auto-rows or grid-auto-columns as specified, and setting the other to auto). grid-auto-flow is also set to either row or column accordingly, with dense if it’s specified.

All other grid sub-properties are reset to their initial values.

Note: Note that you can only specify the explicit or the implicit grid properties in a single grid declaration. The sub-properties you don’t specify are set to their initial value, as normal for shorthands.

In addition to accepting the grid-template shorthand syntax for setting up the explicit grid, the grid shorthand can also easily set up parameters for an auto-formatted grid. For example, grid: auto-flow 1fr / 100px; is equivalent to
grid-template: none / 100px;
grid-auto-flow: row;
grid-auto-rows: 1fr;
grid-auto-columns: auto;

Similarly, grid: none / auto-flow 1fr is equivalent to

grid-template: none;
grid-auto-flow: column;
grid-auto-rows: auto;
grid-auto-columns: 1fr;

8. Placing Grid Items

Every grid item is associated with a grid area, a rectangular set of adjacent grid cells that the grid item occupies. This grid area defines the containing block for the grid item within which the self-alignment properties (justify-self and align-self) determine their actual position. The cells that a grid item occupies also influence the sizing of the grid’s rows and columns, defined in § 12 Grid Sizing.

The location of a grid item’s grid area within the grid is defined by its placement, which consists of a grid position and a grid span:

grid position
The grid item’s location in the grid in each axis. A grid position can be either definite (explicitly specified) or automatic (determined by auto-placement).
grid span
How many grid tracks the grid item occupies in each axis. In a subgridded axis if the *-start or *-end value of its grid-placement properties is auto, then the grid item has an indefinite span, and is determined from its <line-name-list>. Otherwise, a grid item’s grid span is definite, defaulting to 1 in each axis if it can’t be otherwise determined for that axis.

The grid-placement propertiesthe longhands grid-row-start, grid-row-end, grid-column-start, grid-column-end, and their shorthands grid-row, grid-column, and grid-areaallow the author to specify a grid item’s placement by providing any (or none) of the following six pieces of information:

Row Column
Start row-start line column-start line
End row-end line column-end line
Span row span column span

A definite value for any two of Start, End, and Span in a given dimension implies a definite value for the third.

The following table summarizes the conditions under which a grid position or span is definite or automatic:

Position Span
Definite At least one specified line Explicit, implicit, or defaulted span.
Automatic No lines explicitly specified N/A

8.1. Common Patterns for Grid Placement

This section is informative.

The grid-placement property longhands are organized into three shorthands:

grid-area
grid-column grid-row
grid-column-start grid-column-end grid-row-start grid-row-end

8.1.1. Named Areas

An item can be placed into a named grid area (such as those produced by the template in grid-template-areas) by specifying the area’s name in grid-area:

article {
  grid-area: main;
  /* Places item into the named area "main". */
}

An item can also be partially aligned with a named grid area, with other edges aligned to some other line:

.one {
  grid-row-start: main;
  /* Align the row-start edge to the start edge of the "main" named area. */
}

8.1.2. Numeric Indexes and Spans

Grid items can be positioned and sized by number, which is particularly helpful for script-driven layouts:

.two {
  grid-row: 2;    /* Place item in the second row. */
  grid-column: 3; /* Place item in the third column. */
  /* Equivalent to grid-area: 2 / 3; */
}

By default, a grid item has a span of 1. Different spans can be given explicitly:

.three {
  grid-row: 2 / span 5;
  /* Starts in the 2nd row,
     spans 5 rows down (ending in the 7th row). */
}

.four {
  grid-row: span 5 / 7;
  /* Ends in the 7th row,
     spans 5 rows up (starting in the 2nd row). */
}

Note: Note that grid indexes are writing mode relative. For example, in a right-to-left language like Arabic, the first column is the rightmost column.

8.1.3. Named Lines and Spans

Instead of counting lines by number, lines can be referenced by their line name:

.five {
  grid-column: first / middle;
  /* Span from line "first" to line "middle". */
}

Note: Note that if a named grid area has the same name as a line name, the placement algorithm will prefer to use named grid area’s lines instead.

If there are multiple lines of the same name, they effectively establish a named set of grid lines, which can be exclusively indexed by filtering the placement by name:

.six {
  grid-row: text 5 / text 7;
  /* Span between the 5th and 7th lines named "text". */
  grid-row: text 5 / span text 2;
  /* Same as above - start at the 5th line named "text",
     then span across two more "text" lines, to the 7th. */
}

8.1.4. Auto Placement

A grid item can be automatically placed into the next available empty grid cell, growing the grid if there’s no space left.

.eight {
  grid-area: auto; /* Initial value */
}

This can be used, for example, to list a number of sale items on a catalog site in a grid pattern.

Auto-placement can be combined with an explicit span, if the item should take up more than one cell:

.nine {
  grid-area: span 2 / span 3;
  /* Auto-placed item, covering two rows and three columns. */
}

Whether the auto-placement algorithm searches across and adds rows, or searches across and adds columns, is controlled by the grid-auto-flow property.

Note: By default, the auto-placement algorithm looks linearly through the grid without backtracking; if it has to skip some empty spaces to place a larger item, it will not return to fill those spaces. To change this behavior, specify the dense keyword in grid-auto-flow.

8.2. Grid Item Placement vs. Source Order

“With great power comes great responsibility.”

The abilities of the grid-placement properties allow content to be freely arranged and reordered within the grid, such that the visual presentation can be largely disjoint from the underlying document source order. These abilities allow the author great freedom in tailoring the rendering to different devices and modes of presentation e.g. using media queries. However they are not a substitute for correct source ordering.

Correct source order is important for speech, for sequential navigation (such as keyboard navigation), and non-CSS UAs such as search engines, tactile browsers, etc. Grid placement only affects the visual presentation! This allows authors to optimize the document source for non-CSS/non-visual interaction modes, and use grid placement techniques to further manipulate the visual presentation so as to leave that source order intact.

8.3. Line-based Placement: the grid-row-start, grid-column-start, grid-row-end, and grid-column-end properties

Name: grid-row-start, grid-column-start, grid-row-end, grid-column-end
Value: <grid-line>
Initial: auto
Applies to: grid items and absolutely-positioned boxes whose containing block is a grid container
Inherited: no
Percentages: n/a
Computed value: specified keyword, identifier, and/or integer
Canonical order: per grammar
Animation type: discrete
<grid-line> =
  auto |
  <custom-ident> |
  [ <integer> && <custom-ident>? ] |
  [ span && [ <integer> || <custom-ident> ] ]

The grid-row-start, grid-column-start, grid-row-end, and grid-column-end properties determine a grid item’s size and location within the grid by contributing a line, a span, or nothing (automatic) to its grid placement, thereby specifying the inline-start, block-start, inline-end, and block-end edges of its grid area.

Values have the following meanings:

<custom-ident>
First attempt to match the grid area’s edge to a named grid area: if there is a grid line whose line name is <custom-ident>-start (for grid-*-start) / <custom-ident>-end (for grid-*-end), contributes the first such line to the grid item’s placement.

Note: Named grid areas automatically generate implicitly-assigned line names of this form, so specifying grid-row-start: foo will choose the start edge of that named grid area (unless another line named foo-start was explicitly specified before it).

Otherwise, treat this as if the integer 1 had been specified along with the <custom-ident>.

<integer> && <custom-ident>?
Contributes the Nth grid line to the grid item’s placement. If a negative integer is given, it instead counts in reverse, starting from the end edge of the explicit grid.

If a name is given as a <custom-ident>, only lines with that name are counted. If not enough lines with that name exist, all implicit grid lines are assumed to have that name for the purpose of finding this position.

An <integer> value of zero makes the declaration invalid.

span && [ <integer> || <custom-ident> ]
Contributes a grid span to the grid item’s placement such that the corresponding edge of the grid item’s grid area is N lines from its opposite edge in the corresponding direction. For example, grid-column-end: span 2 indicates the second grid line in the endward direction from the grid-column-start line.

If a name is given as a <custom-ident>, only lines with that name are counted. If not enough lines with that name exist, all implicit grid lines on the side of the explicit grid corresponding to the search direction are assumed to have that name for the purpose of counting this span.

For example, given the following declarations:
.grid { grid-template-columns: 100px; }
.griditem { grid-column: span foo / 4; }

The grid container has an explicit grid with two grid lines, numbered 1 and 2. The grid item’s column-end edge is specified to be at line 4, so two lines are generated in the endward side of the implicit grid.

Its column-start edge must be the first "foo" line it can find startward of that. There is no "foo" line in the grid, though, so the only possibility is a line in the implicit grid. Line 3 is not a candidate, because it’s on the endward side of the explicit grid, while the grid-column-start span forces it to search startward. So, the only option is for the implicit grid to generate a line on the startward side of the explicit grid.

An illustration of the result.

If the <integer> is omitted, it defaults to 1. Negative integers or zero are invalid.

auto
The property contributes nothing to the grid item’s placement, indicating auto-placement or a default span of one. (See § 8 Placing Grid Items, above.)

In all the above productions, the <custom-ident> additionally excludes the keywords span and auto.

Given a single-row, 8-column grid and the following 9 named lines:
1  2  3  4  5  6  7  8  9
+--+--+--+--+--+--+--+--+
|  |  |  |  |  |  |  |  |
A  B  C  A  B  C  A  B  C
|  |  |  |  |  |  |  |  |
+--+--+--+--+--+--+--+--+

The following declarations place the grid item between the lines indicated by index:

grid-column-start: 4; grid-column-end: auto;
/* Line 4 to line 5 */

grid-column-start: auto; grid-column-end: 6;
/* Line 5 to line 6 */

grid-column-start: C; grid-column-end: C -1;
/* Line 3 to line 9 */

grid-column-start: C; grid-column-end: span C;
/* Line 3 to line 6 */

grid-column-start: span C; grid-column-end: C -1;
/* Line 6 to line 9 */

grid-column-start: span C; grid-column-end: span C;
/* Error: The end span is ignored, and an auto-placed
   item can’t span to a named line.
   Equivalent to grid-column: span 1;. */

grid-column-start: 5; grid-column-end: C -1;
/* Line 5 to line 9 */

grid-column-start: 5; grid-column-end: span C;
/* Line 5 to line 6 */

grid-column-start: 8; grid-column-end: 8;
/* Error: line 8 to line 9 */

grid-column-start: B 2; grid-column-end: span 1;
/* Line 5 to line 6 */

8.3.1. Grid Placement Conflict Handling

If the placement for a grid item contains two lines, and the start line is further end-ward than the end line, swap the two lines. If the start line is equal to the end line, remove the end line.

If the placement contains two spans, remove the one contributed by the end grid-placement property.

If the placement contains only a span for a named line, replace it with a span of 1.

8.4. Placement Shorthands: the grid-column, grid-row, and grid-area properties

Name: grid-row, grid-column
Value: <grid-line> [ / <grid-line> ]?
Initial: auto
Applies to: grid items and absolutely-positioned boxes whose containing block is a grid container
Inherited: no
Percentages: N/A
Computed value: see individual properties
Animation type: discrete
Canonical order: per grammar

The grid-row and grid-column properties are shorthands for grid-row-start/grid-row-end and grid-column-start/grid-column-end, respectively.

If two <grid-line> values are specified, the grid-row-start/grid-column-start longhand is set to the value before the slash, and the grid-row-end/grid-column-end longhand is set to the value after the slash.

When the second value is omitted, if the first value is a <custom-ident>, the grid-row-end/grid-column-end longhand is also set to that <custom-ident>; otherwise, it is set to auto.

Name: grid-area
Value: <grid-line> [ / <grid-line> ]{0,3}
Initial: auto
Applies to: grid items and absolutely-positioned boxes whose containing block is a grid container
Inherited: no
Percentages: N/A
Computed value: see individual properties
Animation type: discrete
Canonical order: per grammar

The grid-area property is a shorthand for grid-row-start, grid-column-start, grid-row-end and grid-column-end.

If four <grid-line> values are specified, grid-row-start is set to the first value, grid-column-start is set to the second value, grid-row-end is set to the third value, and grid-column-end is set to the fourth value.

When grid-column-end is omitted, if grid-column-start is a <custom-ident>, grid-column-end is set to that <custom-ident>; otherwise, it is set to auto.

When grid-row-end is omitted, if grid-row-start is a <custom-ident>, grid-row-end is set to that <custom-ident>; otherwise, it is set to auto.

When grid-column-start is omitted, if grid-row-start is a <custom-ident>, all four longhands are set to that value. Otherwise, it is set to auto.

Note: The resolution order for this shorthand is row-start/column-start/row-end/column-end, which goes CCW for LTR pages, the opposite direction of the related 4-edge properties using physical directions, like margin.

8.5. Grid Item Placement Algorithm

The following grid item placement algorithm resolves automatic positions of grid items into definite positions, ensuring that every grid item has a well-defined grid area to lay out into. (Grid spans need no special resolution; if they’re not explicitly specified, they default to 1.)

Note: This algorithm can result in the creation of new rows or columns in the implicit grid, if there is no room in the explicit grid to place an auto-positioned grid item.

Every grid cell (in both the explicit and implicit grids) can be occupied or unoccupied. A cell is occupied if it’s covered by the grid area of a grid item with a definite grid position; otherwise, the cell is unoccupied. A cell’s occupied/unoccupied status can change during this algorithm.

To aid in clarity, this algorithm is written with the assumption that grid-auto-flow has row specified. If it is instead set to column, swap all mentions of rows and columns, inline and block, etc. in this algorithm.

Note: The auto-placement algorithm works with the grid items in order-modified document order, not their original document order.

  1. Generate anonymous grid items as described in § 6 Grid Items. (Anonymous grid items are always auto-placed, since their boxes can’t have any grid-placement properties specified.)

  2. Position anything that’s not auto-positioned.

  3. Process the items locked to a given row.

    For each grid item with a definite row position (that is, the grid-row-start and grid-row-end properties define a definite grid position), in order-modified document order:

    “sparse” packing (default behavior)

    Set the column-start line of its placement to the earliest (smallest positive index) line index that ensures this item’s grid area will not overlap any occupied grid cells and that is past any grid items previously placed in this row by this step.

    “dense” packing (dense specified)

    Set the column-start line of its placement to the earliest (smallest positive index) line index that ensures this item’s grid area will not overlap any occupied grid cells.

  4. Determine the columns in the implicit grid.

    Create columns in the implicit grid:

    1. Start with the columns from the explicit grid.

    2. Among all the items with a definite column position (explicitly positioned items, items positioned in the previous step, and items not yet positioned but with a definite column) add columns to the beginning and end of the implicit grid as necessary to accommodate those items.

    3. If the largest column span among all the items without a definite column position is larger than the width of the implicit grid, add columns to the end of the implicit grid to accommodate that column span.

    For example, in the following style fragment:
    #grid {
      display: grid;
      grid-template-columns: repeat(5, 100px);
      grid-auto-flow: row;
    }
    #grid-item {
      grid-column: 4 / span 3;
    }
    

    The number of columns needed is 6. The explicit grid provides 5 columns (from grid-template-columns) with lines number 1 through 6, but #grid-item’s column position means it ends on line 7, which requires an additional column added to the end of the implicit grid.

  5. Position the remaining grid items.

    The auto-placement cursor defines the current “insertion point” in the grid, specified as a pair of row and column grid lines. Initially the auto-placement cursor is set to the start-most row and column lines in the implicit grid.

    The grid-auto-flow value in use determines how to position the items:

    “sparse” packing (default behavior)

    For each grid item that hasn’t been positioned by the previous steps, in order-modified document order:

    If the item has a definite column position:
    1. Set the column position of the cursor to the grid item’s column-start line. If this is less than the previous column position of the cursor, increment the row position by 1.

    2. Increment the cursor’s row position until a value is found where the grid item does not overlap any occupied grid cells (creating new rows in the implicit grid as necessary).

    3. Set the item’s row-start line to the cursor’s row position, and set the item’s row-end line according to its span from that position.

    If the item has an automatic grid position in both axes:
    1. Increment the column position of the auto-placement cursor until either this item’s grid area does not overlap any occupied grid cells, or the cursor’s column position, plus the item’s column span, overflow the number of columns in the implicit grid, as determined earlier in this algorithm.

    2. If a non-overlapping position was found in the previous step, set the item’s row-start and column-start lines to the cursor’s position. Otherwise, increment the auto-placement cursor’s row position (creating new rows in the implicit grid as necessary), set its column position to the start-most column line in the implicit grid, and return to the previous step.

    “dense” packing (dense specified)

    For each grid item that hasn’t been positioned by the previous steps, in order-modified document order:

    If the item has a definite column position:
    1. Set the row position of the cursor to the start-most row line in the implicit grid. Set the column position of the cursor to the grid item’s column-start line.

    2. Increment the auto-placement cursor’s row position until a value is found where the grid item does not overlap any occupied grid cells (creating new rows in the implicit grid as necessary).

    3. Set the item’s row-start line index to the cursor’s row position. (Implicitly setting the item’s row-end line according to its span, as well.)

    If the item has an automatic grid position in both axes:
    1. Set the cursor’s row and column positions to start-most row and column lines in the implicit grid.

    2. Increment the column position of the auto-placement cursor until either this item’s grid area does not overlap any occupied grid cells, or the cursor’s column position, plus the item’s column span, overflow the number of columns in the implicit grid, as determined earlier in this algorithm.

    3. If a non-overlapping position was found in the previous step, set the item’s row-start and column-start lines to the cursor’s position. Otherwise, increment the auto-placement cursor’s row position (creating new rows in the implicit grid as necessary), reset its column position to the start-most column line in the implicit grid, and return to the previous step.

9. Subgrids

A subgrid behaves just like a normal grid container except that:

10. Absolute Positioning

10.1. With a Grid Container as Containing Block

If an absolutely positioned element’s containing block is generated by a grid container, the containing block corresponds to the grid area determined by its grid-placement properties. The offset properties (top/right/bottom/left) then indicate offsets inwards from the corresponding edges of this containing block, as normal.

Note: While absolutely-positioning an element to a grid container does allow it to align to that container’s grid lines, such elements do not take up space or otherwise participate in the layout of the grid.

.grid {
  grid: 1fr 1fr 1fr 1fr / 10rem 10rem 10rem 10rem;
  /* 4 equal-height rows filling the grid container,
     4 columns of 10rem each */
  justify-content: center;
  /* center the grid horizontally within the grid container */
  position: relative;
  /* Establish abspos containing block */
}

.abspos {
  grid-row-start: 1;     /* 1st grid row line = top of grid container */
  grid-row-end: span 2;  /* 3rd grid row line */
  grid-column-start: 3;  /* 3rd grid col line */
  grid-column-end: auto; /* right padding edge */
  /* Containing block covers the top right quadrant of the grid container */

  position: absolute;
  top: 70px;
  bottom: 40px;
  left: 100px;
  right: 30px;
}

Note: Grids and the grid-placement properties are flow-relative, while the offset properties (left, right, top, and bottom) are physical, so if the direction or writing-mode properties change, the grid will transform to match, but the offsets won’t.

Instead of auto-placement, an auto value for a grid-placement property contributes a special line to the placement whose position is that of the corresponding padding edge of the grid container (the padding edge of the scrollable area, if the grid container overflows). These lines become the first and last lines (0th and -0th) of the augmented grid used for positioning absolutely-positioned items.

Note: Thus, by default, the absolutely-positioned box’s containing block will correspond to the padding edges of the grid container, as it does for block containers.

Absolute positioning occurs after layout of the grid and its in-flow contents, and does not contribute to the sizing of any grid tracks or affect the size/configuration of the grid in any way. If a grid-placement property refers to a non-existent line either by explicitly specifying such a line or by spanning outside of the existing implicit grid, it is instead treated as specifying auto (instead of creating new implicit grid lines).

Note: Remember that implicit lines are assumed to have all line names, so a referenced line might exist even though it is not explicitly named.

If the placement only contains a grid span, replace it with the two auto lines in that axis. (This happens when both grid-placement properties in an axis contributed a span originally, and § 8.3.1 Grid Placement Conflict Handling caused the second span to be ignored.)

10.2. With a Grid Container as Parent

An absolutely-positioned child of a grid container is out-of-flow and not a grid item, and so does not affect the placement of other items or the sizing of the grid.

The static position [CSS2] of an absolutely-positioned child of a grid container is determined as if it were the sole grid item in a grid area whose edges coincide with the content edges of the grid container. However, if the grid container parent is also the generator of the absolutely positioned element’s containing block, instead use the grid area determined in § 10.1 With a Grid Container as Containing Block.

Note: Note that this position is affected by the values of justify-self and align-self on the child, and that, as in most other layout models, the absolutely-positioned child has no effect on the size of the containing block or layout of its contents.

11. Alignment and Spacing

After a grid container’s grid tracks have been sized, and the dimensions of all grid items are finalized, grid items can be aligned within their grid areas.

The margin properties can be used to align items in a manner similar to what margins can do in block layout. Grid items also respect the box alignment properties from the CSS Box Alignment Module [CSS-ALIGN-3], which allow easy keyword-based alignment of items in both the rows and columns.

By default, grid items stretch to fill their grid area. However, if justify-self or align-self compute to a value other than stretch or margins are auto, grid items will auto-size to fit their contents.

11.1. Gutters: the row-gap, column-gap, and gap properties

The row-gap and column-gap properties (and their gap shorthand), when specified on a grid container, define the gutters between grid rows and grid columns. Their syntax is defined in CSS Box Alignment 3 §8 Gaps Between Boxes.

The effect of these properties is as though the affected grid lines acquired thickness: the grid track between two grid lines is the space between the gutters that represent them. For the purpose of track sizing, each gutter is treated as an extra, empty, fixed-size track of the specified size, which is spanned by any grid items that span across its corresponding grid line.

Note: Additional spacing may be added between tracks due to justify-content/align-content. See § 12.1 Grid Sizing Algorithm. This space effectively increases the size of the gutters.

If a grid is fragmented between tracks, the gutter spacing between those tracks must be suppressed. Note that gutters are suppressed even after forced breaks, unlike margins.

Gutters only appear between tracks of the implicit grid; there is no gutter before the first track or after the last track. (In particular, there is no gutter between the first/last track of the implicit grid and the “auto” lines in the augmented grid.)

When a collapsed track’s gutters collapse, they coincide exactly—the two gutters overlap so that their start and end edges coincide. If one side of a collapsed track does not have a gutter (e.g. if it is the first or last track of the implicit grid), then collapsing its gutters results in no gutter on either “side” of the collapsed track.

11.2. Aligning with auto margins

This section is non-normative. The normative definition of how margins affect grid items is in § 12 Grid Sizing.

Auto margins on grid items have an effect very similar to auto margins in block flow:

11.3. Inline-axis Alignment: the justify-self and justify-items properties

Grid items can be aligned in the inline dimension by using the justify-self property on the grid item or justify-items property on the grid container, as defined in [CSS-ALIGN-3].

For example, for an English document, the inline axis is horizontal, and so the justify-* properties align the grid items horizontally.

If baseline alignment is specified on a grid item whose size in that axis depends on the size of an intrinsically-sized track (whose size is therefore dependent on both the item’s size and baseline alignment, creating a cyclic dependency), that item does not participate in baseline alignment, and instead uses its fallback alignment as if that were originally specified. For this purpose, <flex> track sizes count as “intrinsically-sized” when the grid container has an indefinite size in the relevant axis.

Note: Whether the fallback alignment is used or not does not change over the course of layout: if a cycle exists, it exists.

11.4. Block-axis Alignment: the align-self and align-items properties

Grid items can also be aligned in the block dimension (perpendicular to the inline dimension) by using the align-self property on the grid item or align-items property on the grid container, as defined in [CSS-ALIGN-3].

If baseline alignment is specified on a grid item whose size in that axis depends on the size of an intrinsically-sized track (whose size is therefore dependent on both the item’s size and baseline alignment, creating a cyclic dependency), that item does not participate in baseline alignment, and instead uses its fallback alignment as if that were originally specified. For this purpose, <flex> track sizes count as “intrinsically-sized” when the grid container has an indefinite size in the relevant axis.

11.5. Aligning the Grid: the justify-content and align-content properties

If the grid’s outer edges do not correspond to the grid container’s content edges (for example, if no columns are flex-sized), the grid tracks are aligned within the content box according to the justify-content and align-content properties on the grid container.

For example, the following grid is centered vertically, and aligned to the right edge of its grid container:
.grid {
  display: grid;
  grid: 12rem 12rem 12rem 12rem / 10rem 10rem 10rem 10rem;
  justify-content: end;
  align-content: center;
}

If there are no grid tracks (the explicit grid is empty, and no tracks were created in the implicit grid), the sole grid line in each axis is aligned with the start edge of the grid container.

Note that certain values of justify-content and align-content can cause the tracks to be spaced apart (space-around, space-between, space-evenly) or to be resized (stretch). If the grid is fragmented between tracks, any such additional spacing between those tracks must be suppressed.

For example, in the following grid, the spanning item’s grid area is increased to accommodate the extra space assigned to the gutters due to alignment:
.wrapper {
  display: grid;
  /* 3-row / 4-column grid container */
  grid: repeat(3, auto) / repeat(4, auto);
  gap: 10px;
  align-content: space-around;
  justify-content: space-between;
}

.item1 { grid-column: 1 / 5; }
.item2 { grid-column: 1 / 3; grid-row: 2 / 4; }
.item3 { grid-column: 3 / 5; }
/* last two items auto-place into the last two grid cells */
Grid with 10px gap and an element spanning all columns.
			          The sum of the columns is less than the width of the grid container.
Grid before alignment
Same grid with increased gaps absorbing the excess grid container width.
			          The spanning element has grown to accommodate the extra space assigned to the gap it crosses.
Grid after alignment

Note that alignment (unlike gap spacing) happens after the grid tracks are sized, so if the track sizes are determined by the contents of the spanned item, it will gain excess space in the alignment stage to accommodate the alignment spacing.

11.6. Grid Container Baselines

The first (last) baselines of a grid container are determined as follows:

  1. Find the first (last) row of the grid container containing at least one grid item.

    If any of the grid items intersecting this row participate in baseline alignment in that row, the grid container’s baseline set is generated from the shared alignment baseline of those grid items.

    Otherwise, the grid container’s first (last) baseline set is generated from the alignment baseline of the first (last) grid item in row-major grid order (according to the writing mode of the grid container). If the grid item has no alignment baseline in the grid’s inline axis, then one is first synthesized from its border edges.

  2. If the grid container does not contain any grid items, the grid container has no first (last) baseline set, and one is synthesized if needed according to the rules of its alignment context. Exit from this algorithm.

Grid-modified document order (grid order) is the order in which grid items are encountered when traversing the grid’s grid cells. If two items are encountered at the same time, they are taken in order-modified document order.

When calculating the baseline according to the above rules, if the box contributing a baseline has an overflow value that allows scrolling, the box must be treated as being in its initial scroll position for the purpose of determining its baseline.

When determining the baseline of a table cell, a grid container provides a baseline just as a line box or table-row does. [CSS2]

See CSS Writing Modes 3 §4.1 Introduction to Baselines and CSS Box Alignment 3 §9 Baseline Alignment Details for more information on baselines.

12. Grid Sizing

This section defines the grid sizing algorithm, which determines the size of all grid tracks and, by extension, the entire grid.

Each track has specified minimum and maximum sizing functions (which may be the same). Each sizing function is either:

The grid sizing algorithm defines how to resolve these sizing constraints into used track sizes.

12.1. Grid Sizing Algorithm

Note: Placement of all grid items, including subgrids and their sub-items, occurs before sizing.

  1. First, the track sizing algorithm is used to resolve the sizes of the grid columns.

    In this process, any grid item which is subgridded in the grid container’s inline axis is treated as empty and its grid items (the grandchildren) are treated as direct children of the grid container (their grandparent). This introspection is recursive.

    Items which are subgridded only in the block axis, and whose grid container size in the inline axis depends on the size of its contents are also introspected: since the size of the item in this dimension can be dependent on the sizing of its subgridded tracks in the other, the size contribution of any such item to this grid’s column sizing (see Resolve Intrinsic Track Sizes) is taken under the provision of having determined its track sizing only up to the same point in the Grid Sizing Algorithm as this itself. E.g. for the first pass through this step, the item will have its tracks sized only through this first step; if a second pass of this step is triggered then the item will have completed a first pass through steps 1-3 as well as the second pass of this step prior to returning its size for consideration in this grid’s column sizing. Again, this introspection is recursive.

    If calculating the layout of a grid item in this step depends on the available space in the block axis, assume the available space that it would have if any row with a definite max track sizing function had that size and all other rows were infinite. If both the grid container and all tracks have definite sizes, also apply align-content to find the final effective size of any gaps spanned by such items; otherwise ignore the effects of track alignment in this estimation.

  2. Next, the track sizing algorithm resolves the sizes of the grid rows.

    In this process, any grid item which is subgridded in the grid container’s block axis is treated as empty and its grid items (the grandchildren) are treated as direct children of the grid container (their grandparent). This introspection is recursive.

    As with sizing columns, items which are subgridded only in the inline axis, and whose grid container size in the block axis depends on the size of its contents are also introspected. (As with sizing columns, the size contribution to this grid’s row sizing is taken under the provision of having determined its track sizing only up to this corresponding point in the algorithm; and again, this introspection is recursive.)

    To find the inline-axis available space for any items whose block-axis size contributions require it, use the grid column sizes calculated in the previous step. If the grid container’s inline size is definite, also apply justify-content to account for the effective column gap sizes.

  3. Then, if the min-content contribution of any grid item has changed based on the row sizes and alignment calculated in step 2, re-resolve the sizes of the grid columns with the new min-content and max-content contributions (once only).

    To find the block-axis available space for any items whose inline-axis size contributions require it, use the grid row sizes calculated in the previous step. If the grid container’s block size is definite, also apply align-content to account for the effective row gap sizes.

    This repetition is necessary for cases where the inline size of a grid item depends on the block size of its grid area. Examples include wrapped column flex containers (flex-flow: column wrap), orthogonal flows (writing-mode), and multi-column containers.
  4. Next, if the min-content contribution of any grid item has changed based on the column sizes and alignment calculated in step 3, re-resolve the sizes of the grid rows with the new min-content and max-content contributions (once only).

    To find the inline-axis available space for any items whose block-axis size contributions require it, use the grid column sizes calculated in the previous step. If the grid container’s inline size is definite, also apply justify-content to account for the effective column gap sizes.

  5. Finally, the grid container is sized using the resulting size of the grid as its content size, and the tracks are aligned within the grid container according to the align-content and justify-content properties.

    Note: This can introduce extra space between tracks, potentially enlarging the grid area of any grid items spanning the gaps beyond the space allotted to during track sizing.

Note: Track sizing in a subgridded dimension treats each item in a given track in that axis as members of the parent grid. This interlacing requires that grid sizing drill down per axis into subgrids, rather than completing both axes as it recurses. Note this means that a subgrid establishing an orthogonal flow would have the order of its track sizing inverted compared to a nested grid.

Once the size of each grid area is thus established, the grid items are laid out into their respective containing blocks. The grid area’s width and height are considered definite for this purpose.

Note: Since formulas calculated using only definite sizes, such as the stretch fit formula, are also definite, the size of a grid item which is stretched is also considered definite.

The following example illustrates how per-axis subgrids are sized:

Suppose we have a parent grid container A which contains an item B that has subgridded columns and contains a grandchild B that has subgridded rows and grandchild D that is simply a nested grid.

<grid-A>
  <grid-B subgrid=columns>
    <grid-C subgrid=rows/>
    <grid-D>
  </grid-B>
<grid-A>

When A sizes its columns it treats B’s items as slotted into to A’s corresponding columns, but when A sizes its rows it treats B as a single item (a grid container with its own rows and some items including items C and D). Similarly when B sizes its rows, it treats C’s items as slotted into B’s rows, but when B sizes its columns, it treats C as a single item, just as it does with D. There is no relationship between C’s rows and A’s rows, because the rows in B are nested, not subgridded.

At a high level, the grid algorithm is:

  1. Size the columns
  2. Size the rows
  3. Adjust the columns (if needed based on final row sizes)

The grid sizing algorithm in this example would thus look like this:

  1. Resolve sizes of A’s grid columns, using the sizes of A’s grid items, treating B as empty but treating its children (including C and D) as items in grid A.

    The grid algorithm simply recurses into D. For C, it’s more complicated:

    1. Size C’s columns.
    2. Size C’s rows by sizing B’s rows.
    3. Adjust C’s columns.
    4. Return C’s final column sizes.

    A correct size for B’s rows requires C’s final column sizes, because the row size depends on the column size, and thus B’s rows could very well depend on C’s final column sizes. To break this cyclic dependency, we need to split the algorithm to depend on the initial approximation of C’s final column sizes, and do the adjustment pass later. So for C, we need to recurse into column sizing only, and pass that initial size up to A for its initial column sizing.

    When we size B’s rows later on, we will size C’s rows (which are subgridded), and finish up C’s sizing by finalizing its columns. If this resulted in a change, we have the opportunity to trigger an adjustment pass for A’s columns during its adjustment pass.

  2. Next, resolve sizes of A’s rows, using the sizes of A’s grid items, treating B as a single item.

    Since B, as a subgrid, has its sizing is split out into the multiple passes, the grid algorithm issues only a row-sizing recursion into B: Size B’s rows, treating D as a single item, requesting its final size, and treating C as an empty item and hoisting its children as items into grid B.

    B returns its final row size, which factors into A’s row sizing pass.

  3. Last, finalize A’s column sizes. If C’s final size changes as a result of the row-sizing pass through B, this should trigger a resizing of B’s columns, which should trigger a resizing pass on A’s column.

12.2. Track Sizing Terminology

min track sizing function
If the track was sized with a minmax() function, this is the first argument to that function. If the track was sized with a <flex> value or fit-content() function, auto. Otherwise, the track’s sizing function.
max track sizing function
If the track was sized with a minmax() function, this is the second argument to that function. Otherwise, the track’s sizing function. In all cases, treat auto and fit-content() as max-content, except where specified otherwise for fit-content().
available grid space
Independently in each dimension, the available grid space is:

Note: auto sizes that indicate content-based sizing (e.g. the height of a block-level box in horizontal writing modes) are equivalent to max-content.

In all cases, clamp the available grid space according to the grid container’s min/max-width/height properties, if they are definite.

free space
Equal to the available grid space minus the sum of the base sizes of all the grid tracks (including gutters), floored at zero. If available grid space is indefinite, the free space is indefinite as well.
span count
The number of grid tracks crossed by a grid item in the applicable dimension.

Note: Remember that gutters are treated as fixed-size tracks—tracks with their min and max sizing functions both set to the gutter’s used size—for the purpose of the grid sizing algorithm. Their widths need to be incorporated into the track sizing algorithm’s calculations accordingly.

12.3. Track Sizing Algorithm

The remainder of this section is the track sizing algorithm, which calculates from the min and max track sizing functions the used track size. Each track has a base size, a <length> which grows throughout the algorithm and which will eventually be the track’s final size, and a growth limit, a <length> which provides a desired maximum size for the base size. There are 5 steps:

  1. Initialize Track Sizes
  2. Resolve Intrinsic Track Sizes
  3. Maximize Tracks
  4. Expand Flexible Tracks
  5. [[#algo-stretch|Expand Stretched auto Tracks]]

12.4. Initialize Track Sizes

Initialize each track’s base size and growth limit. For each track, if the track’s min track sizing function is:

A fixed sizing function
Resolve to an absolute length and use that size as the track’s initial base size.

Note: Indefinite lengths cannot occur, as they’re treated as auto.

An intrinsic sizing function
Use an initial base size of zero.

For each track, if the track’s max track sizing function is:

A fixed sizing function
Resolve to an absolute length and use that size as the track’s initial growth limit.
An intrinsic sizing function
A flexible sizing function
Use an initial growth limit of infinity.

In all cases, if the growth limit is less than the base size, increase the growth limit to match the base size.

Note: Gutters are treated as empty fixed-size tracks for the purpose of the track sizing algorithm.

12.5. Resolve Intrinsic Track Sizes

This step resolves intrinsic track sizing functions to absolute lengths. First it resolves those sizes based on items that are contained wholly within a single track. Then it gradually adds in the space requirements of items that span multiple tracks, evenly distributing the extra space across those tracks insofar as possible.

Note: When this step is complete, all intrinsic base sizes and growth limits will have been resolved to absolute lengths.

Note: Remember that fit-content() and auto max track sizing functions are treated the same as max-content except where explicitly specified otherwise.

  1. Shim baseline-aligned items so their intrinsic size contributions reflect their baseline alignment. For the items in each baseline-sharing group, add a “shim” (effectively, additional margin) on the start/end side (for first/last-baseline alignment) of each item so that, when start/end-aligned together their baselines align as specified.

    Consider these “shims” as part of the items’ intrinsic size contribution for the purpose of track sizing, below. If an item uses multiple intrinsic size contributions, it can have different shims for each one.

    For example, when the grid container has an indefinite size, it is first laid out under min/max-content constraints to find the size, then laid out "for real" with that size (which can affect things like percentage tracks). The "shims" added for each phase are independent, and only affect the layout during that phase.

    Note: Note that both baseline self-aligned and baseline content-aligned items are considered in this step.

    Note: Since grid items whose own size depends on the size of an intrinsically-sized track do not participate in baseline alignment, they are not shimmed.

  2. Size tracks to fit non-spanning items: For each track with an intrinsic track sizing function and not a flexible sizing function, consider the items in it with a span of 1:
    For min-content minimums:
    If the track has a min-content min track sizing function, set its base size to the maximum of the items’ min-content contributions, floored at zero.
    For max-content minimums:
    If the track has a max-content min track sizing function, set its base size to the maximum of the items’ max-content contributions, floored at zero.
    For auto minimums:
    If the track has an auto min track sizing function and the grid container is being sized under a min-/max-content constraint, set the track’s base size to the maximum of its items’ limited min-/max-content contributions (respectively), floored at zero. The limited min-/max-content contribution of an item is (for this purpose) its min-/max-content contribution (accordingly), limited by the max track sizing function (which could be the argument to a fit-content() track sizing function) if that is fixed and ultimately floored by its minimum contribution (defined below).

    Otherwise, set the track’s base size to the maximum of its items’ minimum contributions, floored at zero. The minimum contribution of an item is the smallest outer size it can have. Specifically, if the item’s computed preferred size behaves as auto or depends on the size of its containing block in the relevant axis, its minimum contribution is the outer size that would result from assuming the item’s used minimum size as its preferred size; else the item’s minimum contribution is its min-content contribution. Because the minimum contribution often depends on the size of the item’s content, it is considered a type of intrinsic size contribution.

    Note: For items with a specified minimum size of auto (the initial value), the minimum contribution is usually equivalent to the min-content contributionbut can differ in some cases, see § 6.6 Automatic Minimum Size of Grid Items. Also, minimum contributionmin-content contributionmax-content contribution.

    For min-content maximums:
    If the track has a min-content max track sizing function, set its growth limit to the maximum of the items’ min-content contributions.
    For max-content maximums:
    If the track has a max-content max track sizing function, set its growth limit to the maximum of the items’ max-content contributions. For fit-content() maximums, furthermore clamp this growth limit by the fit-content() argument.

    In all cases, if a track’s growth limit is now less than its base size, increase the growth limit to match the base size.

    Note: This step is a simplification of the steps below for handling spanning items, and should yield the same behavior as running those instructions on items with a span of 1.

  3. Increase sizes to accommodate spanning items crossing content-sized tracks: Next, consider the items with a span of 2 that do not span a track with a flexible sizing function.
    1. For intrinsic minimums: First increase the base size of tracks with an intrinsic min track sizing function by distributing extra space as needed to accommodate these items’ minimum contributions.

      If the grid container is being sized under a min- or max-content constraint, use the items’ limited min-content contributions in place of their minimum contributions here. (For an item spanning multiple tracks, the upper limit used to calculate its limited min-/max-content contribution is the sum of the fixed max track sizing functions of any tracks it spans, and is applied if it only spans such tracks.)

    2. For content-based minimums: Next continue to increase the base size of tracks with a min track sizing function of min-content or max-content by distributing extra space as needed to account for these items' min-content contributions.
    3. For max-content minimums: Next, if the grid container is being sized under a max-content constraint, continue to increase the base size of tracks with a min track sizing function of auto or max-content by distributing extra space as needed to account for these items' limited max-content contributions.

      In all cases, continue to increase the base size of tracks with a min track sizing function of max-content by distributing extra space as needed to account for these items' max-content contributions.

    4. If at this point any track’s growth limit is now less than its base size, increase its growth limit to match its base size.
    5. For intrinsic maximums: Next increase the growth limit of tracks with an intrinsic max track sizing function by distributing extra space as needed to account for these items' min-content contributions. Mark any tracks whose growth limit changed from infinite to finite in this step as infinitely growable for the next step.
      Why does the infinitely growable flag exist?

      Peter Salas explains:

      Consider the following case:
      
      Two "auto" tracks (i.e. minmax(min-content, max-content) minmax(min-content, max-content)).
      Item 1 is in track 1, and has min-content = max-content = 10.
      Item 2 spans tracks 1 and 2, and has min-content = 30, max-content = 100.
      
      After resolving min-content/max-content for the first item, we have this.
      
      track 1: base size = 10 growth limit = 10
      
      track 2: base size = 0 growth limit = infinity
      
      Then we resolve min-content/max-content for the second item.
      
      Phase 1 sets the base size of track 2 to 20 so that the two tracks' base sizes sum to 30.
      Phase 2 does nothing because there are no relevant tracks.
      Phase 3 sets the growth limit of track 2 to 20 so that the two tracks' growth limits sum to 30.
      In phase 4, we need to grow the sum of the growth limits by 70 to accommodate item 2.
      Two options are:
      
      1. Grow each track’s growth limit equally,
        and end up with growth limits = [45, 55].
      2. Grow only the second track’s growth limit,
        and end up with growth limits = [10, 90].
      
      By not considering the just-set growth limit as a constraint during space distribution
      (i.e. by treating it as infinity),
      we get the second result,
      which we considered a better result because the first track remains sized exactly to the first item.
      
    6. For max-content maximums: Lastly continue to increase the growth limit of tracks with a max track sizing function of max-content by distributing extra space as needed to account for these items' max-content contributions. However, limit the growth of any fit-content() tracks by their fit-content() argument.

    Repeat incrementally for items with greater spans until all items have been considered.

  4. Increase sizes to accommodate spanning items crossing flexible tracks: Next, repeat the previous step instead considering (together, rather than grouped by span size) all items that do span a track with a flexible sizing function while
  5. If any track still has an infinite growth limit (because, for example, it had no items placed in it or it is a flexible track), set its growth limit to its base size.

Note: There is no single way to satisfy intrinsic sizing constraints when items span across multiple tracks. This algorithm embodies a number of heuristics which have been seen to deliver good results on real-world use-cases, such as the “game”̣ examples earlier in this specification. This algorithm may be updated in the future to take into account more advanced heuristics as they are identified.

12.5.1. Distributing Extra Space Across Spanned Tracks

To distribute extra space by increasing the affected sizes of a set of tracks as required by a set of intrinsic size contributions,

  1. Maintain separately for each affected base size or growth limit a planned increase, initially set to 0. (This prevents the size increases from becoming order-dependent.)
  2. For each considered item,
    1. Find the space to distribute: Subtract the corresponding size (base size or growth limit) of every spanned track from the item’s size contribution to find the item’s remaining size contribution. (For infinite growth limits, substitute the track’s base size.) This is the space to distribute. Floor it at zero.
      extra-space = max(0, size-contribution - ∑track-sizes)
    2. Distribute space up to limits: Find the item-incurred increase for each spanned track with an affected size by: distributing the space equally among such tracks, freezing a track’s item-incurred increase as its affected size + item-incurred increase reaches its limit (and continuing to grow the unfrozen tracks as needed).

      For base sizes, the limit is its growth limit. For growth limits, the limit is infinity if it is marked as infinitely growable, and equal to the growth limit otherwise.

      Note: If the affected size was a growth limit and the track is not marked infinitely growable, then each item-incurred increase will be zero.

    3. Distribute space beyond limits: If space remains after all tracks are frozen, unfreeze and continue to distribute space to the item-incurred increase of…

      For this purpose, the max track sizing function of a fit-content() track is treated as max-content until it reaches the limit specified as the fit-content() argument, after which it is treated as having a fixed sizing function of that argument.

      Note: This step prioritizes the distribution of space for accommodating space required by the tracks’ min track sizing functions beyond their current growth limits based on the types of their max track sizing functions.

    4. For each affected track, if the track’s item-incurred increase is larger than the track’s planned increase set the track’s planned increase to that value.
  3. Update the tracks' affected sizes by adding in the planned increase so that the next round of space distribution will account for the increase. (If the affected size is an infinite growth limit, set it to the track’s base size plus the planned increase.)

12.6. Maximize Tracks

If the free space is positive, distribute it equally to the base sizes of all tracks, freezing tracks as they reach their growth limits (and continuing to grow the unfrozen tracks as needed).

For the purpose of this step: if sizing the grid container under a max-content constraint, the free space is infinite; if sizing under a min-content constraint, the free space is zero.

If this would cause the grid to be larger than the grid container’s inner size as limited by its max-width/height, then redo this step, treating the available grid space as equal to the grid container’s inner size when it’s sized to its max-width/height.

12.7. Expand Flexible Tracks

This step sizes flexible tracks using the largest value it can assign to an fr without exceeding the available space.

First, find the grid’s used flex fraction:

If the free space is zero or if sizing the grid container under a min-content constraint:
The used flex fraction is zero.
Otherwise, if the free space is a definite length:
The used flex fraction is the result of finding the size of an fr using all of the grid tracks and a space to fill of the available grid space.
Otherwise, if the free space is an indefinite length:
The used flex fraction is the maximum of:

If using this flex fraction would cause the grid to be smaller than the grid container’s min-width/height (or larger than the grid container’s max-width/height), then redo this step, treating the free space as definite and the available grid space as equal to the grid container’s inner size when it’s sized to its min-width/height (max-width/height).

For each flexible track, if the product of the used flex fraction and the track’s flex factor is greater than the track’s base size, set its base size to that product.

12.7.1. Find the Size of an fr

This algorithm finds the largest size that an fr unit can be without exceeding the target size. It must be called with a set of grid tracks and some quantity of space to fill.

  1. Let leftover space be the space to fill minus the base sizes of the non-flexible grid tracks.
  2. Let flex factor sum be the sum of the flex factors of the flexible tracks. If this value is less than 1, set it to 1 instead.
  3. Let the hypothetical fr size be the leftover space divided by the flex factor sum.
  4. If the product of the hypothetical fr size and a flexible track’s flex factor is less than the track’s base size, restart this algorithm treating all such tracks as inflexible.
  5. Return the hypothetical fr size.

12.8. Stretch auto Tracks

This step expands tracks that have an auto max track sizing function by dividing any remaining positive, definite free space equally amongst them. If the free space is indefinite, but the grid container has a definite min-width/height, use that size to calculate the free space for this step instead.

13. Fragmenting Grid Layout

Grid containers can break across pages between rows or columns and inside items. The break-* properties apply to grid containers as normal for the formatting context in which they participate. This section defines how they apply to grid items and the contents of grid items.

The following breaking rules refer to the fragmentation container as the “page”. The same rules apply in any other fragmentation context. (Substitute “page” with the appropriate fragmentation container type as needed.) See the CSS Fragmentation Module [CSS3-BREAK].

The exact layout of a fragmented grid container is not defined in this level of Grid Layout. However, breaks inside a grid container are subject to the following rules:

13.1. Sample Fragmentation Algorithm

This section is non-normative.

This is a rough draft of one possible fragmentation algorithm, and still needs to be severely cross-checked with the [CSS-FLEXBOX-1] algorithm for consistency. Feedback is welcome; please reference the rules above instead as implementation guidance.

  1. Layout the grid following the § 12 Grid Sizing by using the fragmentation container’s inline size and assume unlimited block size. During this step all grid-row auto and fr values must be resolved.
  2. Layout the grid container using the values resolved in the previous step.
  3. If a grid area’s size changes due to fragmentation (do not include items that span rows in this decision), increase the grid row size as necessary for rows that either:
    • have a content min track sizing function.
    • are in a grid that does not have an explicit height and the grid row is flexible.
  4. If the grid height is auto, the height of the grid should be the sum of the final row sizes.
  5. If a grid area overflows the grid container due to margins being collapsed during fragmentation, extend the grid container to contain this grid area (this step is necessary in order to avoid circular layout dependencies due to fragmentation).

If the grid’s height is specified, steps three and four may cause the grid rows to overflow the grid.

14. Privacy and Security Considerations

Grid introduces no new privacy leaks, or security considerations beyond "implement it correctly".

15. Changes

15.1. Changes since the August 2020 CR

Changes since the December 2019 CSS Grid Layout Level 2 Working Draft

None, except the incorporation of the full text of CSS Grid level 1.

See Changes during Working Draft for previous changes.

15.2. Additions Since Level 2

The following features have been added since Level 1:

16. Acknowledgements

Many thanks to Mats Palmgren of Mozilla, without whose support and feedback the subgrid feature would not be able to move forward. Thanks also to Daniel Tonon, who insisted on intelligent handling of gaps in subgrids and contributed illustrations; and Rachel Andrew and Jen Simmons who helped bridge the feedback gap between the CSS Working Group and the Web design/authoring community.

Lastly, the acknowledgements section of CSS Grid Level 2 would be incomplete without acknowledgement of everyone who made the monumental task of CSS Grid Level 1 possible.

Conformance

Document conventions

Conformance requirements are expressed with a combination of descriptive assertions and RFC 2119 terminology. The key words “MUST”, “MUST NOT”, “REQUIRED”, “SHALL”, “SHALL NOT”, “SHOULD”, “SHOULD NOT”, “RECOMMENDED”, “MAY”, and “OPTIONAL” in the normative parts of this document are to be interpreted as described in RFC 2119. However, for readability, these words do not appear in all uppercase letters in this specification.

All of the text of this specification is normative except sections explicitly marked as non-normative, examples, and notes. [RFC2119]

Examples in this specification are introduced with the words “for example” or are set apart from the normative text with class="example", like this:

This is an example of an informative example.

Informative notes begin with the word “Note” and are set apart from the normative text with class="note", like this:

Note, this is an informative note.

Advisements are normative sections styled to evoke special attention and are set apart from other normative text with <strong class="advisement">, like this: UAs MUST provide an accessible alternative.

Conformance classes

Conformance to this specification is defined for three conformance classes:

style sheet
A CSS style sheet.
renderer
A UA that interprets the semantics of a style sheet and renders documents that use them.
authoring tool
A UA that writes a style sheet.

A style sheet is conformant to this specification if all of its statements that use syntax defined in this module are valid according to the generic CSS grammar and the individual grammars of each feature defined in this module.

A renderer is conformant to this specification if, in addition to interpreting the style sheet as defined by the appropriate specifications, it supports all the features defined by this specification by parsing them correctly and rendering the document accordingly. However, the inability of a UA to correctly render a document due to limitations of the device does not make the UA non-conformant. (For example, a UA is not required to render color on a monochrome monitor.)

An authoring tool is conformant to this specification if it writes style sheets that are syntactically correct according to the generic CSS grammar and the individual grammars of each feature in this module, and meet all other conformance requirements of style sheets as described in this module.

Partial implementations

So that authors can exploit the forward-compatible parsing rules to assign fallback values, CSS renderers must treat as invalid (and ignore as appropriate) any at-rules, properties, property values, keywords, and other syntactic constructs for which they have no usable level of support. In particular, user agents must not selectively ignore unsupported component values and honor supported values in a single multi-value property declaration: if any value is considered invalid (as unsupported values must be), CSS requires that the entire declaration be ignored.

Implementations of Unstable and Proprietary Features

To avoid clashes with future stable CSS features, the CSSWG recommends following best practices for the implementation of unstable features and proprietary extensions to CSS.

Non-experimental implementations

Once a specification reaches the Candidate Recommendation stage, non-experimental implementations are possible, and implementors should release an unprefixed implementation of any CR-level feature they can demonstrate to be correctly implemented according to spec.

To establish and maintain the interoperability of CSS across implementations, the CSS Working Group requests that non-experimental CSS renderers submit an implementation report (and, if necessary, the testcases used for that implementation report) to the W3C before releasing an unprefixed implementation of any CSS features. Testcases submitted to W3C are subject to review and correction by the CSS Working Group.

Further information on submitting testcases and implementation reports can be found from on the CSS Working Group’s website at https://www.w3.org/Style/CSS/Test/. Questions should be directed to the [email protected] mailing list.

CR exit criteria

For this specification to be advanced to Proposed Recommendation, there must be at least two independent, interoperable implementations of each feature. Each feature may be implemented by a different set of products, there is no requirement that all features be implemented by a single product. For the purposes of this criterion, we define the following terms:

independent
each implementation must be developed by a different party and cannot share, reuse, or derive from code used by another qualifying implementation. Sections of code that have no bearing on the implementation of this specification are exempt from this requirement.
interoperable
passing the respective test case(s) in the official CSS test suite, or, if the implementation is not a Web browser, an equivalent test. Every relevant test in the test suite should have an equivalent test created if such a user agent (UA) is to be used to claim interoperability. In addition if such a UA is to be used to claim interoperability, then there must one or more additional UAs which can also pass those equivalent tests in the same way for the purpose of interoperability. The equivalent tests must be made publicly available for the purposes of peer review.
implementation
a user agent which:
  1. implements the specification.
  2. is available to the general public. The implementation may be a shipping product or other publicly available version (i.e., beta version, preview release, or "nightly build"). Non-shipping product releases must have implemented the feature(s) for a period of at least one month in order to demonstrate stability.
  3. is not experimental (i.e., a version specifically designed to pass the test suite and is not intended for normal usage going forward).

The specification will remain Candidate Recommendation for at least six months.

Index

Terms defined by this specification

Terms defined by reference

References

Normative References

[CSS-ALIGN-3]
Elika Etemad; Tab Atkins Jr.. CSS Box Alignment Module Level 3. 21 April 2020. WD. URL: https://www.w3.org/TR/css-align-3/
[CSS-BOX-4]
Elika Etemad. CSS Box Model Module Level 4. 21 April 2020. WD. URL: https://www.w3.org/TR/css-box-4/
[CSS-BREAK-4]
Rossen Atanassov; Elika Etemad. CSS Fragmentation Module Level 4. 18 December 2018. WD. URL: https://www.w3.org/TR/css-break-4/
[CSS-CASCADE-4]
Elika Etemad; Tab Atkins Jr.. CSS Cascading and Inheritance Level 4. 18 August 2020. WD. URL: https://www.w3.org/TR/css-cascade-4/
[CSS-DISPLAY-3]
Tab Atkins Jr.; Elika Etemad. CSS Display Module Level 3. 19 May 2020. CR. URL: https://www.w3.org/TR/css-display-3/
[CSS-FLEXBOX-1]
Tab Atkins Jr.; et al. CSS Flexible Box Layout Module Level 1. 19 November 2018. CR. URL: https://www.w3.org/TR/css-flexbox-1/
[CSS-IMAGES-3]
Tab Atkins Jr.; Elika Etemad; Lea Verou. CSS Images Module Level 3. 10 October 2019. CR. URL: https://www.w3.org/TR/css-images-3/
[CSS-INLINE-3]
Dave Cramer; Elika Etemad; Steve Zilles. CSS Inline Layout Module Level 3. 27 August 2020. WD. URL: https://www.w3.org/TR/css-inline-3/
[CSS-OVERFLOW-3]
David Baron; Elika Etemad; Florian Rivoal. CSS Overflow Module Level 3. 3 June 2020. WD. URL: https://www.w3.org/TR/css-overflow-3/
[CSS-POSITION-3]
Elika Etemad; et al. CSS Positioned Layout Module Level 3. 19 May 2020. WD. URL: https://www.w3.org/TR/css-position-3/
[CSS-PSEUDO-4]
Daniel Glazman; Elika Etemad; Alan Stearns. CSS Pseudo-Elements Module Level 4. 25 February 2019. WD. URL: https://www.w3.org/TR/css-pseudo-4/
[CSS-SIZING-3]
Tab Atkins Jr.; Elika Etemad. CSS Box Sizing Module Level 3. 23 October 2020. WD. URL: https://www.w3.org/TR/css-sizing-3/
[CSS-SYNTAX-3]
Tab Atkins Jr.; Simon Sapin. CSS Syntax Module Level 3. 16 July 2019. CR. URL: https://www.w3.org/TR/css-syntax-3/
[CSS-TEXT-3]
Elika Etemad; Koji Ishii; Florian Rivoal. CSS Text Module Level 3. 29 April 2020. WD. URL: https://www.w3.org/TR/css-text-3/
[CSS-VALUES-3]
Tab Atkins Jr.; Elika Etemad. CSS Values and Units Module Level 3. 6 June 2019. CR. URL: https://www.w3.org/TR/css-values-3/
[CSS-VALUES-4]
Tab Atkins Jr.; Elika Etemad. CSS Values and Units Module Level 4. 31 January 2019. WD. URL: https://www.w3.org/TR/css-values-4/
[CSS-WRITING-MODES-4]
Elika Etemad; Koji Ishii. CSS Writing Modes Level 4. 30 July 2019. CR. URL: https://www.w3.org/TR/css-writing-modes-4/
[CSS2]
Bert Bos; et al. Cascading Style Sheets Level 2 Revision 1 (CSS 2.1) Specification. 7 June 2011. REC. URL: https://www.w3.org/TR/CSS21/
[CSS3-BREAK]
Rossen Atanassov; Elika Etemad. CSS Fragmentation Module Level 3. 4 December 2018. CR. URL: https://www.w3.org/TR/css-break-3/
[CSS3-WRITING-MODES]
Elika Etemad; Koji Ishii. CSS Writing Modes Level 3. 10 December 2019. REC. URL: https://www.w3.org/TR/css-writing-modes-3/
[CSSOM]
Simon Pieters; Glenn Adams. CSS Object Model (CSSOM). 17 March 2016. WD. URL: https://www.w3.org/TR/cssom-1/
[INFRA]
Anne van Kesteren; Domenic Denicola. Infra Standard. Living Standard. URL: https://infra.spec.whatwg.org/
[MEDIAQUERIES-5]
Dean Jackson; Florian Rivoal; Tab Atkins Jr.. Media Queries Level 5. 31 July 2020. WD. URL: https://www.w3.org/TR/mediaqueries-5/
[RFC2119]
S. Bradner. Key words for use in RFCs to Indicate Requirement Levels. March 1997. Best Current Practice. URL: https://tools.ietf.org/html/rfc2119
[WEB-ANIMATIONS-1]
Brian Birtles; et al. Web Animations. 11 October 2018. WD. URL: https://www.w3.org/TR/web-animations-1/

Informative References

[CSS-MULTICOL-1]
Håkon Wium Lie; Florian Rivoal; Rachel Andrew. CSS Multi-column Layout Module Level 1. 15 October 2019. WD. URL: https://www.w3.org/TR/css-multicol-1/
[HTML]
Anne van Kesteren; et al. HTML Standard. Living Standard. URL: https://html.spec.whatwg.org/multipage/

Property Index

Name Value Initial Applies to Inh. %ages Anim­ation type Canonical order Com­puted value
grid <'grid-template'> | <'grid-template-rows'> / [ auto-flow && dense? ] <'grid-auto-columns'>? | [ auto-flow && dense? ] <'grid-auto-rows'>? / <'grid-template-columns'> none grid containers see individual properties see individual properties see individual properties per grammar see individual properties
grid-area <grid-line> [ / <grid-line> ]{0,3} auto grid items and absolutely-positioned boxes whose containing block is a grid container no N/A discrete per grammar see individual properties
grid-auto-columns <track-size>+ auto grid containers no see Track Sizing by computed value type per grammar see Track Sizing
grid-auto-flow [ row | column ] || dense row grid containers no n/a discrete per grammar specified keyword(s)
grid-auto-rows <track-size>+ auto grid containers no see Track Sizing by computed value type per grammar see Track Sizing
grid-column <grid-line> [ / <grid-line> ]? auto grid items and absolutely-positioned boxes whose containing block is a grid container no N/A discrete per grammar see individual properties
grid-column-end <grid-line> auto grid items and absolutely-positioned boxes whose containing block is a grid container no n/a discrete per grammar specified keyword, identifier, and/or integer
grid-column-start <grid-line> auto grid items and absolutely-positioned boxes whose containing block is a grid container no n/a discrete per grammar specified keyword, identifier, and/or integer
grid-row <grid-line> [ / <grid-line> ]? auto grid items and absolutely-positioned boxes whose containing block is a grid container no N/A discrete per grammar see individual properties
grid-row-end <grid-line> auto grid items and absolutely-positioned boxes whose containing block is a grid container no n/a discrete per grammar specified keyword, identifier, and/or integer
grid-row-start <grid-line> auto grid items and absolutely-positioned boxes whose containing block is a grid container no n/a discrete per grammar specified keyword, identifier, and/or integer
grid-template none | [ <'grid-template-rows'> / <'grid-template-columns'> ] | [ <line-names>? <string> <track-size>? <line-names>? ]+ [ / <explicit-track-list> ]? none grid containers see individual properties see individual properties see individual properties per grammar see individual properties
grid-template-areas none | <string>+ none grid containers no n/a discrete per grammar the keyword none or a list of string values
grid-template-columns none | <track-list> | <auto-track-list> | subgrid <line-name-list>? none grid containers no refer to corresponding dimension of the content area if the list lengths match, by computed value type per item in the computed track list (see and ); discrete otherwise per grammar the keyword none or a computed track list
grid-template-rows none | <track-list> | <auto-track-list> | subgrid <line-name-list>? none grid containers no refer to corresponding dimension of the content area if the list lengths match, by computed value type per item in the computed track list (see and ); discrete otherwise per grammar the keyword none or a computed track list

Issues Index

The first bullet point of the above list means that implicit tracks get serialized as part of grid-template-rows/etc., despite the fact that an author cannot actually specify implicit track sizes in those properties! So grid-template-rows and grid-template-columns values might not round-trip correctly:
const s = getComputedStyle(gridEl);
gridEl.style.gridTemplateRows = s.gridTemplateRows;
// Code like this should be a no-op,
// but if there are any implicit rows,
// this will convert them into explicit rows,
// possibly changing how grid items are positioned
// and altering the overall size of the grid!

This is an accidental property of an early implementation that leaked into later implementations without much thought given to it. We intend to remove it from the spec, but not until after we’ve defined a CSSOM API for getting information about implicit tracks, as currently this is the only way to get that information and a number of pages rely on that.

The CSS Working Group is considering whether to also return used values for the grid-placement properties and is looking for feedback, especially from implementors. See discussion.